Development of "[11C]kits" for a fast, efficient and reliable production of carbon-11 labeled radiopharmaceuticals for Positron Emission Tomography.

Translation of carbon-11 labeled PET tracers to clinical settings is currently impeded by the technical difficulties associated with [11C]CO2 conversion into the highly reactive methylating agents [11C]CH3I and [11C]CH3OTf using automated modules relying on stationary valves. Here we describe development of the first in its kind "[11C]kit" for production of carbon-11 radiotracer using disposable manifolds. This method proved to be very reliable and allows for consecutive production of PET tracers with minimal intervals between the syntheses.

Synthesis optimization of 2-(4-N-[11C]methylaminophenyl)-6-hydroxybenzothiazole ([11C]PIB), ß-amyloid PET imaging tracer for Alzheimer's disease diagnosis.

[11C]PIB is the most used amyloid plaques-specific positron-emitting radiotracers. The radiosynthesis of this compound, carried out by methylation of its precursor with [11C]methyl triflate in 2-butanone, has been improved optimizing the initial concentration and the purification method. Two HPLC methods were compared: good radiochemical yields, specific activities, and chemical purity above 98% were achieved by using as eluant acetonitrile/citrate and formulation in 10% ethanol.

Synthesis of [11C]palmitic acid for PET imaging using a single molecular sieve 13X cartridge for reagent trapping, radiolabeling and selective purification.

INTRODUCTION: Radiolabeled fatty acids are valuable metabolic tracers for PET imaging. Carbon-11 is widely used in clinical PET studies due to the prevalence of facile techniques enabling the incorporation of [(11)C]CO2 and [(11)C]CH3 into molecules and a short half-life (20.4 min) that translates into low patient dose. However, the short half-life considerably limits the time for radiosynthesis. Furthermore, the majority of the syntheses of [(11)C]palmitic acid in common use employ high starting [(11)C]CO2 activities and/or expensive equipment. METHODS: [(11)C]CO2 was trapped with greater than 99.99% efficiency by a three stage cartridge packed with molecular sieve 13X, 100-120 mesh. The labeling of n-pentadecylmagnesium bromide took place in 5 min in the cartridge, and the [(11)C]palmitic acid product was selectively eluted in ethanol following alkaline and acidic washes of the column. RESULTS: The system reliably produced more than 925 MBq (25 mCi) of [(11)C]palmitic acid suitable for human use from 7.4 GBq (200 mCi) of [(11)C]CO2 in 8 min from end-of-bombardment. CONCLUSIONS: We have exploited the properties of the inexpensive molecular sieve 13X to develop a miniature, disposable and leak tight "gas capture" system for the rapid labeling and purification of [(11)C]fatty acids in good yield and >99% radiochemical purity. The rapidity of the synthesis and purification allows small [(11)C]CO2 starting activities to be used, and with no requirement for expensive synthesis equipment or facilities, the system can be implemented in any radiopharmaceutical center.

Cryogenic molecular separation system for radioactive (11)C ion acceleration.

A (11)C molecular production/separation system (CMPS) has been developed as part of an isotope separation on line system for simultaneous positron emission tomography imaging and heavy-ion cancer therapy using radioactive (11)C ion beams. In the ISOL system, (11)CH4 molecules will be produced by proton irradiation and separated from residual air impurities and impurities produced during the irradiation. The CMPS includes two cryogenic traps to separate specific molecules selectively from impurities by using vapor pressure differences among the molecular species. To investigate the fundamental performance of the CMPS, we performed separation experiments with non-radioactive (12)CH4 gases, which can simulate the chemical characteristics of (11)CH4 gases. We investigated the separation of CH4 molecules from impurities, which will be present as residual gases and are expected to be difficult to separate because the vapor pressure of air molecules is close to that of CH4. We determined the collection/separation efficiencies of the CMPS for various amounts of air impurities and found desirable operating conditions for the CMPS to be used as a molecular separation device in our ISOL system.

The design and performance of a portable handheld (11)CO2 delivery system.

We constructed a hand-held device to efficiently trap [(11)C]CO2 from the cyclotron target, safely transport up to 3.7GBq (100mCi) doses to remote sites and release it without the need for a liquid cryogen. The system consists of a 180W furnace and a miniature molecular sieve trap (80-100mg; 80-100mesh 13×) placed inside a lead pig weighing 11.1kg. The overall [(11)C]CO2 delivery efficiency of the device is ~82% (> 99% trapping efficiency). Radiation dose rates measured at 30cm from the surface of the pig are <43.5µSv/h (5mR/h) up to 2.59GBq (70mCi).

Fate of (14)C-organic pollutant residues in composted sludge after application to soil.

Organic micropollutants may be present in biosolids, leading to soil contamination when they are recycled in agriculture. A sludge spiked with (14)C-labelled glyphosate (GLY), sodium linear dodecylbenzene sulphonate (LAS), fluoranthene (FLT) or 4-n-nonylphenol (NP) was composted with green waste and the fate of the (14)C-micropollutant residues remaining after composting was assessed after the compost application to the soil. (14)C-residues were mineralised in the soil and represented after 140d 20-32% of the initial activity for LAS, 16-25% for GLY, 6-9% for FLT and 4-7% for NP. The (14)C-residues at the end of composting that could not be extracted with methanol or ammonia were minimally remobilised or even increased for FLT. After 140d, non-extractable residues represented 38-52% of all of the (14)C-residues remaining in the soil for FLT, 50-67% for GLY, 91-92% for NP and 94-97% for LAS and in most cases, less than 1% of the (14)C-residues were water soluble, suggesting a low direct availability for leaching and microbial or plant assimilation. FLT was identified as the main compound among the methanol-extractable (14)C-residues that may be potentially available. The fate of the (14)C-organic pollutant residues in composts after application to soil could be assessed through a sequential chemical extraction scheme and depended on the chemical nature of the pollutant.

Biodegradation of 14C-dicofol in wastewater aerobic treatment and sludge anaerobic biodigestion.

Organic micropollutants are often found in domestic and industrial effluents. Thus, it is important to learn their fate, the metabolites generated and their sorption during biological treatment processes. This work investigated the biodegradation of 14C-dicofol organochloride during wastewater aerobic treatment and sludge anaerobic biodigestion. The performance of these processes was evaluated by physical-chemical parameters. Radioactivity levels were monitored in both treatments, and residues of dicofol (DCF) and dichlorobenzophenone (DBP) were quantified by HPLC/UV. The efficiency of the aerobic and anaerobic processes was slightly reduced in the presence of DCF and DBP. After aerobic treatment, only 0.1% of DCF was mineralized, and 57% of radioactivity remained sorbed on biological sludge as DBP. After 18 days of anaerobiosis, only 3% of DCF and 5% of DBP were detected in the sludge. However, 70% of radioactivity remained in the sludge, probably as other metabolites. Dicofol was biodegraded in the investigated process, but not mineralized.

Rapid and efficient purification of positron emission tomography probes by hydrophilic interaction chromatography.

A rapid and efficient preparative high-performance liquid chromatographic procedure was established to purify short-lived positron emission tomography radio-probes. This method is based on hydrophilic interaction chromatography utilizing a semi-preparative silica column (10 mm I.D.) and a high volatile organic mobile phase (>90% acetonitrile). In nine different radiopharmaceuticals studied, six compounds could be separated from the unlabeled precursor with good resolution and faster elution than its precursor. These characteristics enabled significant shortening of the separation and evaporation processes in the manufacture of short-lived radiopharmaceuticals. Several (11)C-radiopharmaceuticals could be prepared within one half-life of carbon-11 (20.4 min), including radiosynthesis, purification and formulation steps with sufficient radiochemical/chemical purity and high levels of radioactivity/specific radioactivity.

Automated synthesis of 11C-acetoacetic acid, a key alternate brain fuel to glucose.

An automated, one-pot radio-synthesis module for the routine preparation of 1-[(11)C]acetoacetic acid has been developed. The enolate anion of acetone was reacted with [(11)C]CO(2) in tetrahydrofuran (THF), followed by hydrolysis and purification by ion-exchange chromatography. The total synthesis time was 18 min and radiochemical yield was 34% after decay correction. HPLC analysis showed < or =3% impurities while residual THF (< or =200 ppm) and ethanol (< or =500 ppm) were well under the tolerable limits for human studies.

Evaluation of gas chromatographic isotope fractionation and process contamination by carbon in compound-specific radiocarbon analysis.

The relevance of both modern and fossil carbon contamination as well as isotope fractionation during preparative gas chromatography for compound-specific radiocarbon analysis (CSRA) was evaluated. Two independent laboratories investigated the influence of modern carbon contamination in the sample cleanup procedure and preparative capillary gas chromatography (pcGC) of a radiocarbon-dead 3,3',4,4',5,5'-hexachlorobiphenyl (PCB 169) reference. The isolated samples were analyzed for their 14C/12C ratio by accelerator mass spectrometry. Sample Delta14C values of -996 +/- 20 and -985 +/- 20 per thousand agreed with a Delta14C of -995 +/- 20 per thousand for the unprocessed PCB 169, suggesting that no significant contamination by nonfossil carbon was introduced during the sample preparation process at either laboratory. A reference compound containing a modern 14C/12C ratio (vanillin) was employed to evaluate process contamination from fossil C. No negative bias due to fossil C was observed (sample Delta14C value of 165 +/- 20 per thousand agreed with Delta14C of 155 +/- 12 per thousand for the unprocessed vanillin). The extent of isotopic fractionation that can be induced during pcGC was evaluated by partially collecting the vanillin model compound of modern 14C/12C abundance. A significant change in the delta13C and delta14C values was observed when only parts of the eluting peak were collected (delta13C values ranged from -15.75 to -49.91 per thousand and delta14C values from -82.4 to +4.71 per thousand). Delta14C values, which are normalized to a delta13C of -25 per thousand, did not deviate significantly (-58.9 to -5.8 per thousand, considering the uncertainty of approximately +/-20 per thousand). This means that normalization of radiocarbon results to a delta13C of -25 per thousand, normally performed to remove effects of environmental isotope fractionation on 14C-based age determinations, also cor-rects sufficiently for putative isotopic fractionation that may occur during pcGC isolation of individual compounds for CSRA.

Respirometric 13C flux analysis, Part I: design, construction and validation of a novel multiple reactor system using on-line membrane inlet mass spectrometry.

A novel method for (13)C flux analysis based on on-line CO(2) labeling measurements is presented. This so-called respirometric (13)C flux analysis requires multiple parallel (13)C labeling experiments using differently labeled tracer substrates. In Part I of the work, a membrane-inlet mass spectrometry-based measurement system with 6 parallel reactors with each 12 ml liquid volume and associated experimental and computational methods for the respirometric (13)C data acquisition and evaluation are described. Signal dynamics after switching between membrane probes follow exactly first-order allowing extrapolation to steady state. Each measurement cycle involving 3 reactors takes about 2 min. After development of a dynamic calibration method, the suitability and reliability of the analysis was examined with a lysine-producing mutant of Corynebacterium glutamicum using [1-(13)C(1)], [6-(13)C(1)], [1,6-(13)C(2)] glucose. Specific rates of oxygen uptake and CO(2) production were estimated with an error less than +/-0.3 mmol g(-1) h(-1) and had +/-3% to +/-10% deviations between parallel reactors which is primarily caused by inaccuracies in initial biomass concentration. The respiratory quotient could be determined with an uncertainty less than +/-0.02 and varied only +/-3% between reactors. Fractional labeling of CO(2) was estimated with much higher precision of about +/-0.001 to +/-0.005. The detailed statistical analysis suggested that these data should be of sufficient quality to allow physiological interpretation and metabolic flux estimation. The obtained data were applied for the respirometric (13)C metabolic flux analysis in Part II.

Respirometric 13C flux analysis--Part II: in vivo flux estimation of lysine-producing Corynebacterium glutamicum.

A novel method for metabolic flux studies of central metabolism which is based on respirometric (13)C flux analysis, i.e., parallel (13)C tracer studies with online CO(2) labeling measurements is applied to flux quantification of a lysine-producing mutant of Corynebacterium glutamicum. For this purpose, 3 respirometric (13)C labeling experiments with [1-(13)C(1)], [6-(13)C(1)] and [1,6-(13)C(2)] glucose were carried out in parallel. All fluxes comprising the reactions of glycolysis, of TCA cycle, of C3- and C4-metabolite interconversion and of lysine biosynthesis as well as the net reactions in the pentose phosphate pathway could be quantified solely using experimental data obtained from CO(2) labeling and extracellular rate measurements. At key branch points, 68+/-5% of glucose 6-phosphate were observed to be metabolized into pentose phosphate pathway and 48+/-1% of pyruvate into TCA cycle via pyruvate dehydrogenase. The results showed a good agreement with the previous studies using (13)C tracer cultivation and GC/MS analysis of proteinogenic amino acids. Also, respiratory quotient calculated from flux estimates using redox balance showed a high accordance with the value determined directly from the measured specific rates of O(2) consumption and CO(2) production. The results strongly support that the respirometric (13)C metabolic flux analysis is suited as an alternative to the conventional methods to study functional and regulatory activities of cells. The developed method is applicable to study growing or non-growing cells, primary and secondary metabolism and immobilized cells. Due to the non-accumulating nature of CO(2) labeling and instantaneous nature of the resulting fluxes, the method can also be used for dynamic profiling of metabolic activities. Therefore, it is complementary to conventional methods for metabolic flux analysis.

Preparative separation of underivatized amino acids for compound-specific stable isotope analysis and radiocarbon dating of hydrolyzed bone collagen.

Analysis of stable and radioactive isotopes from bone collagen provides useful information to archaeologists about the origin and age of bone artifacts. Isolation and analysis of single amino acids from the proteins can provide additional and more accurate information by removing contamination and separating a bulk isotope signal into its constituent parts. In this paper, we report a new method for the separation and isolation of underivatized amino acids from bone collagen, and their analysis by isotope ratio MS and accelerator MS. RP chromatography is used to separate the amino acids with nonpolar side chains, followed by an ion pair separation to isolate the remaining amino acids. The method produces single amino acids with little or no contamination from the separation process and allows for the measurement of accurate stable isotope ratios and pure samples for radiocarbon dating.

Purification of carbon-11 PET radiotracers from unlabeled precursors by preparative HPLC and SPE.

A general methodology for the rapid purification of carbon-11 positron emission tomography (PET) radiotracers from radiolabeling reaction mixtures has been developed. Preparative HPLC and solid-phase extraction (SPE) techniques are described which can separate some commonly used radiopharmaceuticals such as [(11)C]raclopride, [(11)C]beta-CFT and [(11)C]choline from their unlabeled precursors.

Comparison of three different purification methods for the routine preparation of [11C] Metomidate.

PET with (R)-[O-methyl-11C] metomidate ([11C] MTO) is an attractive method for the characterisation of adrenal masses discriminating lesions of adrenal cortical origin from noncortical lesions. [11C] MTO was prepared by the reaction of [11C] methyliodide with the corresponding free acid. Three purification methods have been compared. The method of choice uses preparative HPLC with a ready-to-use weak acidic solvent.

Synthesis and biologic evaluation of (11)c-methyl-d-glucoside, a tracer of the sodium-dependent glucose transporters.

UNLABELLED: This study aimed to synthesize and to evaluate the biologic characteristics of (11)C labeled methyl-D-glucoside, a nonmetabolizable tracer that is selectively transported by sodium-dependent glucose transporters (SGLTs). METHODS: (11)C-Methyl-D-glucoside was prepared by methylation of glucose with (11)C-methyl triflate and was obtained as a mixture of anomers that were separated with high-performance liquid chromatography. The biodistribution of both the D- and L-isomers was determined in mice, and the presence of metabolites in the blood was investigated. The intrarenal distribution of (11)C-methyl-D-glucoside in mouse kidneys was visualized using autoradiography. Transport of alpha-methyl-D-glucoside and beta-methyl-D-glucoside by the human sodium-D-glucose cotransporter hSGLT1 was characterized after expression of hSGLT1 in oocytes of Xenopus laevis. RESULTS: The developed preparation procedure provided (11)C-methyl-D-glucoside in a total synthesis time of 20 min and a yield of 30% (decay corrected). The alpha- and beta-anomers of methyl-D-glucoside were reabsorbed from the primary urinary filtrate and showed only a minimal urinary excretion. Because methyl-L-glucoside was not reabsorbed and the reabsorption of methyl-D-glucoside was blocked by phlorizin, sodium-D-glucose cotransporters were critically involved. beta-Methyl-D-glucoside was accumulated in the kidneys to a higher extent than the alpha-anomer, suggesting that the basolateral efflux from the tubular cells is slower for the beta-anomer. Autoradiography showed that methyl-D-glucoside was accumulated throughout the renal cortex, suggesting that both sodium-D-glucose cotransporters expressed in kidney, SGLT1 and SGLT2, are involved in the uptake. The tracer was found to be metabolically stable and did not accumulate in red blood cells, which indicates that methyl-D-glucoside is not transported by the sodium-independent transporter GLUT1. Electrical measurements in Xenopus oocytes revealed that alpha-methyl-D-glucoside and beta-methyl-D-glucoside are transported by the human SGLT1 transporter with similar maximal transport rates and apparent Michaelis-Menten constant values. CONCLUSION: (11)C-Methyl-D-glucoside is a selective tracer of sodium-dependent glucose transport and can be used to visualize the function of this transporter with PET in vivo.

Preparation of [11C] radioligands with high specific radioactivity on a commercial PET tracer synthesizer.

High specific radioactivity is required for receptor studies with PET. Hereby we wish to report our experience using Nuclear Interface PET Tracer Synthesizer for preparation of Carbon-11 radioligands and module's modifications, which allowed to achieve high specific radioactivity.

Syntheses of [carbonyl-11C]2-(2-benzoylphenoxy)-N-phenylacetamide from [11C]carbon monoxide by the Suzuki and the Stille reactions.

Syntheses of [carbonyl-11C]2-(2-benzoylphenoxy)-N-phenylacetamide, a radiolabeled inhibitor of human immunodeficiency virus type 1 (HIV 1) reverse transcriptase, were achieved by applying palladium-mediated cross-coupling reactions with insertion of [11C]carbon monoxide. Our interest was focused for the present on a comparison of the Stille and Suzuki methods, using trimethylphenylstannane or phenylboronic acid as alternative coupling reagents, respectively. The Suzuki variant gave a much higher amount of [11C]CO radioactivity trapped in the reaction mixture, but a significant loss of product occurred due to adsorption phenomena on the potassium carbonate present in the heterogeneous reaction mixture. The labeled product was isolated in only 20% yield (based on trapped [11C]CO, not corrected for decay). According to Stille, the reaction provided a product that could be isolated more easily but it did not increase the final yield of the target compound due to a low trapping efficiency for [11C]CO. Both methods were performed in an overall synthesis time of 30min, starting from [11C]CO2, and gave a product with a specific radioactivity of at least 30GBq/micromol. The Stille method as well as the Suzuki reaction allowed the synthesis of a radiochemically pure product in aqueous acetonitrile.

A remote-controlled high pressure reactor for radiotracer synthesis with [11C]carbon monoxide.

[11C]Carbon monoxide is a versatile building block for the synthesis of PET radiotracers. However, the difficulty of trapping [11C]CO in a small solvent volume has limited its utility. We wish to report the details of a simple, remotely operated High Pressure Reactor (HiPR) system for trapping and reacting practical quantities of [11C]CO. All parts used in the HiPR are commercially available, providing an inexpensive and easily assembled system. A number of compounds have been synthesized using the HiPR via palladium mediated reactions with [11C]CO, an aryl halide, and a nucleophile dissolved in dioxane. For example, AMPA receptor modulator [11C]CX546 was synthesized from its respective precursors in 37% isolated yield, uncorrected from trapped [11C]CO.

Effect of vehicle on brain uptake of [11C]toluene.

With the goal of investigating the pharmacokinetics of the abused solvent, toluene we have adapted the rapid coupling of methyl iodide with tributylphenylstannane mediated by palladium(0) complex to the synthesis of no-carrier-added [11C]toluene starting with 11CH(3)I. Two methods for purification and formulation of the tracer were developed. The first one yielded [11C]toluene dissolved in dimethylacetamide/saline solution, for the second one we adapted supercritical fluid technology where the tracer was purified using and conventional C(18) HPLC column and pure supercritical CO(2) fluid as a mobile phase operating at 2000 psi. Formulation of the tracer in cyclodextrin resulted in a significantly higher integrated uptake and distribution volume values. Additionally, we observed higher uptake and slower clearance of 11C-toluene in white matter, consistent with higher lipid content and neurotoxicological evidence indicating restricted and diffuse white matter changes in toluene abusers. This trend was observed when either DMA or cyclodextrin was used as a vehicle. It appears then, that the choice of a vehicle affected only the degree of bioavailability, but not the regional brain pharmacokinetics. Finally, we demonstrated the effect of a decreased percent difference between DV values for the studies performed on the same day, that is, test/retest variability was lower for all brain regions in beta-cyclodextrin experiments. Present results clearly demonstrate that the choice of a vehicle has a significant effect on tracer uptake and should be considered as a potential factor contributing to the pharmacokinetic measurements.