Potential radiopharmaceuticals for the detection of ocular melanoma

In order to investigate the possibility of using [1-¹¹C] labelled 3,4-dihydroxyphenylalanine (DOPA) and tyrosine as radiopharmaceuticals for the detection of eye melanoma, the biodistributions of the same 1- and 3-¹⁴C-labelled compounds were investigated in Syrian golden hamsters with Greene melanoma. The results of these investigations were compared with positron emission tomography (PET) images of ¹¹C labelled DOPA and tyrosine. The synthesis of these ¹¹C labelled compounds procures of DL mixture, from which D and L forms can be separated. One h after intravenous injection, both ¹⁴C labelled DL-, L-and D-DOPA showed a high uptake in tumour tissue, that of DL- and D-DOPA being the highest. These high uptakes, together with relatively low uptake in bone, skin and eye resulted in high tumour/non tumour ratio (for DL-DOPA 5.9, 4.5 and 6.6 respectively). Extraction of the tumour tissue with trichloroacetic acid showed that L-DOPA was mainly incorporated into melanin, whereas D-DOPA was not. Also, the uptake 1 h after intravenous injection of 1-¹⁴C-L- and DL-tyrosine into the tumour were high, but L- and DL- were less different; tumour/non tumour ratios were favorable. PET images of the tumour obtained 40–80 min after injection of the [1-¹¹C] labelled DOPA and tyrosine confirmed that melanoma detection was promising and that D-DOPA produced a better melanoma image than L-DOPA.     

PET measurements of hyperthermia-induced suppression of protein synthesis in tumors in relation to effects on tumor growth

Hyperthermia-induced metabolic changes in tumor tissue have been monitored by PET. Uptake of L-[1-11C]tyrosine in rhabdomyosarcoma tissue of Wag/Rij rats was dose-dependently reduced after local hyperthermia treatment at 42, 45, or 47 degrees C. Tumor blood flow, as measured by PET with 13NH3, appeared to be unchanged. The L-[1-11C]tyrosine uptake data were compared to uptake data of L-[1-14C]tyrosine and with data on the incorporation of L-[1-14C]tyrosine into tumor proteins. After intravenous injection, the 14C data were obtained from dissected tumor tissue. Heat-induced inhibition of the incorporation of L-[1-14C]tyrosine into tumor proteins tallied with the L-[1-11C]tyrosine uptake data. Heat-induced inhibition of amino acid uptake in the tumor correlated well with regression of tumor growth. It is concluded that PET using L-[1-11C]tyrosine is eligible for monitoring the effect of hyperthermia on tumor growth.     

The Bücherer-Strecker synthesis of D- and L-(1-11C)tyrosine and the in vivo study of L-(1-11C)tyrosine in human brain using positron emission tomography

The synthesis of D- and L-(1-11C)tyrosine, starting with 11C-cyanide, is reported. DL-(1-11C)Tyrosine was prepared by the Bücherer-Strecker reaction, from carrier added 11C-cyanide with an incorporation of 80% in 20 min. The isolation of the pure D- and L-amino acid isomers from the enantiomeric mixture was accomplished within 15 min by preparative HPLC using a chiral stationary phase and a phosphate buffer as the mobile phase. Typically, the total synthesis time was 50 min (including purification) from end of trapping of 11C-cyanide, with a radiochemical yield of D- and L-amino acid of 40%-60%. The D- and L-(1-11C)tyrosine were both obtained optically pure, with a carrier added specific activity of 0.3-0.5 Ci/mmol and a radiochemical purity better than 99%. The 11C labelled L-tyrosine was used in an in vivo study in the human brain using positron emission tomography (PET).     

PET studies with L-[1-11C]tyrosine, L-[methyl-11C]methionine and 18F-fluorodeoxyglucose in prolactinomas in relation to bromocryptine treatment

Aspects of metabolism in prolactinomas were investigated by positron emission tomography using L-[1-11C]tyrosine, L-[methyl-11C]methionine and 18F-fluorodeoxyglucose (18FDG). Using L-[1-11C]tyrosine, four patients were monitored prior to and 18 h after an injection of 50 mg bromocriptine. At 18 h after bromocriptine intervention, L-[1-11C]tyrosine uptake into tumour was reduced with 28% (P less than 0.07). A correlation analysis of the bromocriptine-induced decrease in L-[1-11C]tyrosine uptake and the reduction of serum prolactin levels indicated that the action of bromocriptine on prolactin synthesis and prolactin release is not coupled. In the untreated situation, the four patients were investigated with 18FDG as well, but the prolactinomas could not be visualized. Three untreated patients were studied with L-[methyl-11C]methionine. The tumour-imaging potential of L-[methyl-11C]methionine and L-[1-11C]tyrosine appeared to be nearly equivalent for prolactinomas. Unlike prolactinoma tissue, the salivary glands showed a pronounced preference for L-[1-11C]tyrosine as compared to L-[methyl-11C]methionine. L-[1-11C]tyrosine is a valuable tool to obtain information on the metabolism and treatment of prolactinomas.     

Different brain radioactivity curves in a PET study with [11C]beta-CIT labelled in two different positions.

The cocaine congener 2beta-carbomethoxy-3beta-(4'-iodophenyl)tropane (beta-CIT) has a chemical structure that enables labelling with carbon-11 either by N-methylation or by O-methylation. The regional brain uptake of [N-methyl-11C]beta-CIT and [O-methyl-11C]beta-CIT was compared in cynomolgus monkeys using positron emission tomography (PET). The striatal uptake of radioactivity after intravenous injection of [O-methyl-11C]beta-CIT reached a plateau at 30-40 min, whereas the uptake of [N-methyl-11C]beta-CIT increased continuously during the time of the PET measurement. Two of the putative labelled metabolites, [N-methyl-11C]beta-CIT-acid and [O-methyl-11C]nor-beta-CIT were prepared and examined with PET to investigate if they may enter the brain and thus add to the radioactivity uptake obtained with [11C]beta-CIT. Less than 0.4% of injected [N-methyl-11C]beta-CIT-acid entered the brain whereas 5-6% of [O-methyl-11C]nor-beta-CIT entered the brain and accumulated in the striatum and in the thalamus. The fraction of [O-methyl-11C]nor-beta-CIT obtained in plasma after intravenous injection of [O-methyl-11C]nor-beta-CIT, however, never exceeded 3%. Consequently, the formation of [N-methyl-11C]beta-CIT-acid and [O-methyl-11C]nor-beta-CIT cannot be the explanation for the different time-activity curves in the monkey brain demonstrated with [11C]beta-CIT labelled in two different positions. An unidentified labelled lipophilic metabolite, detected in monkey plasma after injection of [O-methyl-11C]beta-CIT, remains as the only possible explanation for the differences between [N-methyl-11C]beta-CIT and [O-methyl-11C]beta-CIT.     

Radiation-induced inhibition of tumor growth as monitored by PET using L-[1-11C]tyrosine and fluorine-18-fluorodeoxyglucose.

The potential use of PET to monitor radiotherapeutic effects on tumors has been evaluated with L-[1-11C]tyrosine and 18FDG. Single x-ray doses of 10, 30, or 50 Gy have been applied to rhabdomyosarcoma tumors growing in the flank of rats. Dose-dependent reductions of tracer uptake were registered by PET 4 and 12 days after treatment. These later effects on tracer uptake appeared to correlate with changes in tumor volume. Therefore, PET using L-[1-11C]tyrosine and 18FDG is suitable to monitor kinetics of tumor growth and tumor regression after radiotherapy. Direct effect on tracer uptake was not observed within 8 hr after irradiation. This indicates that, using PET, early predictions on the outcome of radiotherapy are not possible. When combining a radiation treatment with hyperthermia, radiation-induced inhibition of tumor growth was clearly enhanced. Tracer uptake remained at the pretreatment value, possibly due to invasion of host cells. From these experiments, it can be concluded that it is difficult to monitor a combined treatment of radiation and hyperthermia by PET.     

Biodistribution of [11C] methylaminoisobutyric acid, a tracer for PET studies on system A amino acid transport in vivo

[N-methyl-11C]alpha-Methylaminoisobutyric acid (11C-MeAIB) is a potentially useful tracer for positron emission tomography (PET) studies on hormonally regulated system A amino acid transport. 11C-MeAIB is a metabolically stable amino acid analogue specific for system A amino acid transport. We evaluated the biodistribution of 11C-MeAIB in rats and humans to estimate the usefulness of the tracer for in vivo human PET studies, for example, on regulation of system A amino acid transport and on tumour imaging. Healthy Sprague-Dawley rats (n=14) were killed 5, 20, 40 or 60 min after the injection of 11C-MeAIB, and the tissue samples were weighed and counted for 11C radioactivity. Ten lymphoma patients with relatively limited tumour burden underwent whole-body (WB) PET imaging with 11C-MeAIB. In addition, three other patients had dynamic PET scanning of the head and neck area, and the tracer uptake was quantitated by calculating the kinetic influx constants (Ki values) for the tracer. In animal studies, the highest activity was detected in the kidney, pancreas, adrenal gland and intestines. In humans, the highest activity was found in the salivary glands, and after that in the kidney and pancreas, similar to the results in animal studies. Rapid uptake was also detected in the skeletal muscle. In the graphical analysis, linear plots were obtained, and the mean fractional tracer uptake values (Ki) of the parotid glands (n=3) and cervical muscles (n=3) were 0.039+/-0.008 min(-1) and 0.013+/-0.006 min(-1), respectively. The Ki value of the tumour (n=1) was 0.064 min(-1). Higher uptake of 11C-MeAIB into the tumour tissue was encountered. These results encourage further 11C-MeAIB PET studies in humans on the physiology and pathology of system A amino acid transport and on tumour detection.     

In vivo labeling of endothelin receptors with [(11)C]L-753,037: studies in mice and a dog.

Endothelin (ET) is a potent mammalian vasoconstrictive peptide and a pressor agent. Its 3 isoforms, ET-1, ET-2, and ET-3, mediate several physiologic actions in several organ systems, binding to 2 major receptor subtypes: ET(A) and ET(B). This study was undertaken to evaluate [(11)C]L-753,037 [(+)-(5S,6R,7R)-2-butyl-7-[2-((2S)-2-carboxy-propyl)-4-methoxyphenyl]-5-(3,4-methylenedioxyphenyl)cyclopenteno [1,2-beta]pyridine-6-carboxylate), a new mixed ET receptor A and B antagonist, as a tracer for in vivo labeling of ET receptors in mice and a dog. METHODS: [(11)C]L-753,037 was synthesized, purified, and formulated from a normethyl precursor, L-843,974, and [(11)C]H(3)I. The tracer was studied for its in vivo kinetics, biodistribution, and ET receptor binding characteristics in mice. In the dog, PET imaging was performed to evaluate binding of [(11)C]L-753,037 to ET receptors in the heart. Specificity of binding was studied in the heart with the selective ET(A) antagonist L-753,164. RESULTS: Kinetic studies in mice showed highest tracer uptake at 5 min after injection in liver (25.0 percentage injected dose per gram [%ID/g]), kidneys (18.7 %ID/g), lungs (15.2 %ID/g), and heart (5.6 %ID/g). Initial high uptake in liver, lungs, and kidneys was followed by rapid washout during the next 10 min and a very slow clearance during the time of observation (2 h after injection). By contrast, the radioactivity in the heart remained constant over 2 h. Administration of both ET(A) (L-753,164) and mixed ET(A)/ET(B) (L-753,137) receptor antagonists resulted in dose-dependent inhibition of [(11)C]L-753,037 binding in mouse heart, lungs, and kidneys but not in the liver. Radioactivity in the brain was very low, indicating that the tracer does not cross the blood-brain barrier. In the dog, a dynamic PET study of the heart showed high tracer accumulation at 55-95 min after injection. Injection of L-753,164 at 30 min before [(11)C]L-753,037 administration led to a significant reduction in tracer binding. [(11)C]methyl triphenyl phosphonium was used as a tracer for reference images of the dog heart muscle. CONCLUSION: The results suggest that [(11)C]L-753,037 binds to ET receptors in vivo and is, therefore, a promising candidate for investigation of these receptors and their occupancy by ET receptor antagonists using PET.     

Comparison of L-[1-11C]methionine and L-methyl-[11C]methionine for measuring in vivo protein synthesis rates with PET

To evaluate the feasibility of using either L-[1-11C]-methionine or L-[methyl-11C]methionine for measuring protein synthesis rates by positron emission tomography (PET) in normal and neoplastic tissues, distribution and metabolic studies with 14C- and 11C-labeled methionines were carried out in rats bearing Walker 256 carcinosarcoma. The tissue distributions of the two 14C-labeled methionines were similar except for liver tissue. Similar distribution patterns were observed in vivo by PET using 11C-labeled methionines. The highest 14C incorporation rate into the protein-bound fraction was found in the liver followed by tumor, brain, and pancreas. The incorporation rates in liver and pancreas were different for the two methionines. By chloroform-methanol fractionation of these four tissues, in liver significantly different amounts of 14C were observed in macromolecules. Also in brain tissue slight differences were found. By HPLC analyses of the protein-free fractions of plasma, tumor, and brain tissue at 60 min after injection, for both methionines several 14C-labeled metabolites in different amounts, were detected. About half of the 14C-labeled material in the protein-free fraction was found to be methionine. In these three tissues the amount of nonprotein metabolites and [14C]bicarbonate amount ranged from 10% to 17% and 12% to 15% for L-[1-14C]methionine and L-[methyl-14C]methionine, respectively. From these results it can be concluded that the minor metabolic pathways have to be investigated in order to quantitatively model the protein synthesis by PET.     

Metabolic studies with L-[1-14C]tyrosine for the investigation of a kinetic model to measure protein synthesis rates with PET

To evaluate a kinetic model for measuring protein synthesis rates by positron emission tomography (PET) in neoplastic and normal tissue, metabolic studies with L-[1-14C]tyrosine were carried out. As an animal model, rats bearing Walker 256 carcinosarcoma were used. Within 60 min after injection, several metabolic parameters were measured. The highest radioactivity uptake, expressed as the differential absorption ratio, was found in pancreas, followed by liver, tumor, and brain. A rapid decarboxylation was observed during the first 15 min. After 60 min, 7.4% of the total injected 14C was expired as 14CO2. In plasma a significant amount of [14C]bicarbonate was detected, but in tissue the amount was negligible. Protein incorporation increased with time. The incorporation rate was the highest in the liver followed by pancreas, tumor, and brain tissues. At 60 min after injection, more than approximately 80% of the 14C in tissue was protein bound. In plasma after a rapid clearance during the first 15 min, the total 14C level increased rapidly and paralleled the increase of protein-bound 14C. As nonprotein [14C]metabolites, in plasma, tumor and brain tissues, p-hydroxyphenylpyruvic acid, p-hydroxyphenyllactic acid, and unidentified metabolites were observed by high performance liquid chromatography. The formation of 14C-labeled 3,4-dihydroxyphenylalanine was found to be negligible. The total amount of these nonprotein metabolites increased with time. At 60 min after injection the percentages of the total nonprotein metabolites and [14C]bicarbonate were only 5.0%, 1.9%, and 3.7% in plasma, tumor and brain tissue, respectively. From our data it is concluded that [11C]carboxylic-labeled tyrosine would be a suitable radiopharmaceutical for measuring protein synthesis rates in neoplastic and normal tissue by PET.     

Quantitative analysis of dopamine synthesis in human brain using positron emission tomography with L-[beta-11C]DOPA

BACKGROUND AND OBJECTIVES: To estimate the presynaptic function of the central dopaminergic system, the rate of endogenous dopamine synthesis has been measured by using L-[beta-C]DOPA or 6-[F]fluoro-L-DOPA with positron emission tomography. However, the regional kinetics of L-[beta-C]DOPA in human brain have not been investigated in detail. In the present study, the regional kinetics of L-[beta-C]DOPA in normal human brain and the accuracy of the method for quantifying L-[beta-C]DOPA kinetics, employing reference regions, were investigated. METHODS: After intravenous injection of L-[beta-C]DOPA, dynamic scanning was performed on ten healthy subjects for 89 min. The overall uptake rate constant K was calculated by the kinetic and graphical approaches, in which the occipital cortex was used as a reference brain region. RESULTS: Regional distribution of K was similar to those of dopamine D2 receptor. A significant negative correlation was observed between the neutral amino acid concentration in plasma and the influx rate constant through the blood-brain barrier (K1). The K values calculated by graphical approach were in good agreement with the values calculated by kinetic approach for both experimental and simulated data. CONCLUSIONS: The regional distribution of K corresponds to that of the nigrostriatal and mesolimbic dopaminergic system. Negative correlation between neutral amino acid concentration and K1 supports the suggestion that L-DOPA is transported in a competitive fashion via the same carrier system as neutral amino acids at the blood-brain barrier. Because the graphical approach can obviate the need for an arterial input function, it is useful for investigating the rate of regional dopamine synthesis in neuropsychiatric and neurodegenerative diseases.     

Localization of 11C-radiopharmaceuticals in the Greene melanoma of hamsters

Seventy Syrian golden hamsters bearing SC transplants of Greene melanoma were used to evaluate the degree of tumour uptake of several 11C-radiopharmaceuticals selected for their potential specificity for melanoma. Tissue distribution studies were performed at 30 and 60 min after IV injection of 11C-compounds and compared with the 24-h uptake of 67Ga-citrate. Gamma camera images were also compared. The highest tumour uptake at 1 h was observed with 11C-methionine (2.42% +/- 0.72%) and although activity in liver, spleen and kidney exceeded that in melanoma the tumour was demonstrated on gamma camera imaging. Melanoma localisation of 11C-chlorpromazine, 11C-flunitrazepam and 11C-ketanserine was comparable at 1% of the dose injected per gram of tumour. High activity in other organs, particularly liver, exceeded uptake in melanoma and attempts at tumour imaging were unsuccessful. Tumour accumulation of 11C-methiodide quinuclidinyl benzylate (MQNB), an 11C-imidazobenzodiazepine (Ro-15-1788) and 14C-pimozide was low and imaging studies were not attempted. None of the 11C-radiopharmaceuticals evaluated for melanoma affinity matched that of 67Ga-citrate. The 24-h tumour uptake of 67Ga-citrate was 4.07% +/- 1.37% dose injected per gram which allowed delineation of the melanoma by gamma camera imaging.     

Kinetics of [11C]N,N-dimethylphenylethylamine in mice and humans: potential for measurement of brain MAO-B activity

Carbon-11-labeled N,N-dimethylphenylethylamine ([11C]DMPEA) was synthesized by the reaction of N-methylphenylethylamine with [11C]methyl iodide. This newly synthesized radiotracer was developed for the purpose of in vivo measurement of monoamine oxidase-B activity in the brain using a metabolic trapping method. Initially, biodistribution was investigated in mice. The rapid and high uptake of 11C radioactivity in the brain was observed following intravenous injection of [11C]DMPEA, the peak of which was reached at 1 min, followed by a decrease at 1-5 min and slowly thereafter. The kinetics of [11C]DMPEA in the human brain were determined using positron emission tomography (PET) and showed that 11C radioactivity increased gradually over 60 min following initial rapid uptake of 11C radioactivity, with basal ganglia and thalamus showing high accumulation.     

Syntheses and pharmacological evaluation of two potent antagonists for dopamine D4 receptors: [11C]YM-50001 and N-[2-[4-(4-Chlorophenyl)-piperizin-1-yl]ethyl]-3-[11C]methoxybenzamide

Two benzamide derivatives as dopamine D4 receptor antagonists, YM-50001(4) and N- [2-[4-(4-chlorophenyl]piperizin-1-yl]ethyl]-3-methoxybenzamide (9), were labeled by positron-emitter (11C), and their pharmacological specificities to dopamine D4 receptors were examined by quantitative autoradiography and positron emission tomography (PET). Radiosyntheses were accomplished by O-methylation of corresponding phenol precursors (5 and 10) with [11C]CH3I followed by HPLC purifications. In vitro binding on rat brain slices showed different distribution patterns and pharmacological properties between the two radioligands. The [11C]4 showed the highest binding in the striatum, which was inhibited not only by 10 microM 4 but also by 10 microM raclopride, a selective dopamine D2 receptor antagonist. In contrast, [11C]9 showed the highest binding in the cerebral cortex, which was inhibited by several D4 receptor antagonists (9, RBI-254, L-745,870), but not by any other receptor ligands (D1/D5, D2/D3, 5-HT1A, 5-HT2A, sigma1 and alpha1) tested. In vivo brain distribution of [11C]9 in rat showed the highest uptake in the frontal cortex, a region that has a high density of D4 receptors. These results indicate that the pharmacological property of [11C]9 matches the rat brain D4 receptors, but that of [11C]4 rather appears to match the rat brain D2 receptors. The results for the benzamide [11C]9 prompted us to further evaluate its potential as a PET radioligand for D4 receptors by employing PET on monkey brain. Unfortunately, in contrast to rats, neither specific binding nor differences in regional uptake of radioactivity were observed in monkey brain after intravenous 11C]9 injection. Based on that specific activities of radioligands might be critical in mapping the neurotransmitter receptors if they are only faintly expressed in the brain, 11C]9 with an extremely high specific activity (1810 GBq/micromol) was used for PET study. However, the effort to determine the specific binding for D4 failed. These results indicate that both of the benzamide derivatives would not be suitable radioligands for D4 receptors with PET.     

Visualisation and assessment of the protein synthesis rate of lung cancer using carbon-11 tyrosine and positron emission tomography

This study evaluated the potential role of L-(1-(11)C)-tyrosine positron emission tomography (TYR PET) for visualisation and quantification of protein metabolism in lung cancer. Dynamic TYR PET scans of the thorax were performed in 17 patients with lung cancer. Protein synthesis rate (PSR in micromol/min x l) and standardised uptake value (SUV, corrected for body measurements) of tumour tissue and contralateral normal tissue were calculated before and after chemotherapy or radiotherapy. All tumours [11 non-small cell lung carcinomas (NSCLCs), five small cell lung carcinomas (SCLCs), and one pleural mesothelioma] were visualised as a hot spot. The median PSR in tumour tissue was higher than that in corresponding contralateral normal lung tissue before [1.88 micromol/min x l (range 1.10-3.42) vs 0.40 micromol/min x l (range 0.12-0.86); P=0.003] and after treatment [1.33 micromol/min x l (range 0.45-2.21) vs 0.28 micromol/min x l (range 0.18-0.51); P<0.02]. In contrast to PSR of normal lung tissue, PSR of tumour tissue decreased significantly after therapy (P=0.03). Before therapy, no significant difference in PSR between NSCLCs and SCLCs was observed, but after therapy the PSR differed significantly between the subgroups [1.69 micromol/min x l (range 0.63-2.78) for NSCLC vs 0.67 micromol/min x l (range 0.45-0.92) for SCLC; P=0.03], irrespective of the treatment modality. The median SUV of tumour tissue was higher than that in corresponding contralateral normal lung both before and after therapy. Only a weak correlation between PSR and SUV was found when the latter was corrected for body surface area or lean body mass. Carbon-11 labelled tyrosine appears to be a good tracer for visualising lung cancer. PSR of tumour tissue can be used to quantify reduction in the metabolic rate of the tumour. Future studies need to be performed to determine whether TYR PET will supply additional clinical information with treatment implications in patients with lung cancer.     

Synthesis and preclinical evaluation of [<Superscript>11</Superscript>C]PAQ as a PET imaging tracer for VEGFR-2

Purpose  (R,S)-N-(4-Bromo-2-fluorophenyl)-6-methoxy-7-((1-methyl-3-piperidinyl)methoxy)-4-quinazolinamine (PAQ) is a tyrosine kinase inhibitor with high affinity for the vascular endothelial growth factor receptor 2 (VEGFR-2), which plays an important role in tumour angiogenesis. The aim of this work was to develop and evaluate in mice the ¹¹C-labelled analogue as an in vivo tracer for VEGFR-2 expression in solid tumours. Methods  [¹¹C]PAQ was synthesized by an N-methylation of desmethyl-PAQ using [¹¹C]methyl iodide. The tracer’s pharmacokinetic properties and its distribution in both subcutaneous and intraperitoneal tumour models were evaluated with positron emission tomography (PET). [¹⁸F]FDG was used as a reference tracer for tumour growth. PET results were corroborated by ex vivo and in vitro phosphor imaging and immunohistochemical analyses. Results  In vitro assays and PET in healthy animals revealed low tracer metabolism, limited excretion over 60 min and a saturable and irreversible binding. Radiotracer uptake in subcutaneous tumour masses was low, while focal areas of high uptake (up to 8% ID/g) were observed in regions connecting the tumour to the host. Uptake was similarly high but more distributed in tumours growing within the peritoneum. The pattern of radiotracer uptake was generally different from that of the metabolic tracer [¹⁸F]FDG and correlated well with variations in VEGFR-2 expression determined ex vivo by immunohistochemical analysis. Conclusion  These results suggest that [¹¹C]PAQ has potential as a noninvasive PET tracer for in vivo imaging of VEGFR-2 expression in angiogenic “hot spots”.     

Automatic synthesis of L-[beta-11C]amino acids using an immobilized enzyme column.

We have developed a system for the automatic synthesis of L-[beta-11C]amino acids for i.v. injection by means of enzyme-mediated reactions from 11CO2 via 11CH3I and D,L-[beta-11C]alanine as labeled intermediates. This system, which incorporates an ultrafilter cartridge sterilized by electron beam irradiation and a column packed with immobilized enzymes, was effective for eliminating enzymes and endotoxins that may contaminate the product. Using this system, 1.3 +/- 0.5 GBq of 5-hydroxy-L-[beta-11C]tryptophan with a radiochemical purity of 97.1 +/- 0.6% and a specific activity of 39.6 +/- 8 GBq/mumol a pH value of 4 could be obtained in about 32 min (n = 3, at EOS). No endotoxin, enzyme, or bacteria was detected in the product. L-[beta-11C]dihydroxyphenylalanine (L-[beta-11C]DOPA) was also synthesized using this system.     

Carbon-11 labelled tyrosine to study tumor metabolism by positron emission tomography (PET)

To measure the rate of protein synthesis in human neoplasms by positron emission tomography, we prepared no carrier added DL-(1-11C)-tyrosine by 11C-carboxylation of the appropriate alpha-lithioisocyanide followed by hydrolysis of the isocyanide function and removal of the protecting methoxy group. The purification, resolution and solvent switch to saline was performed by high performance liquid chromatography (HPLC). DL-(1-11C)-Tyrosine in 0.1 N NaH2PO4 buffer was prepared with a radiochemical yield of 8%-16% (EOS, 35 min). The enantiomeric separation and solvent switch to saline were achieved in 5 min and 10 min respectively. Consequently L-(1-11C)-tyrosine in physiological saline was obtained in 2%-4% radiochemical yield. Tumor accumulation in rats with the experimental WALKER 256 carcinosarcoma was observed for both the L- and D-isomer. Using positron emission tomography a tumor/muscle ratio of two was observed for the L-isomer 15 min after injection. The corresponding figure for the D-isomer was 2.5. The first clinical results with DL-(1-11C)-tyrosine show accumulation of radioactivity in meningioma, a primary breast carcinoma and in liver metastases of a colonic carcinoma.     

Potential radiopharmaceuticals for the detection of ocular melanoma. Part I. 5-iodo-2-thiouracil derivatives

The tissue distribution of a number of 5-[131I]-iodo-2-thiouracil derivatives was measured in Syrian golden hamsters with Greene melanoma. These compounds were rapidly (in less than 1 h) distributed in all tissues, while in most tissues fast elimination (T1/2 1-3 h) was observed. Because of retention of the 131I activity in the tumour, high tumour/non-tumour tissue ratios were found (e.g. tumour/eye 2.3-10, tumour/skin 1.5-3) suggesting that some of these compounds might be used as melanoma delineating agents, when labelled with 123I.     

Evaluation of [11C]GB67, a novel radioligand for imaging myocardial alpha 1-adrenoceptors with positron emission tomography

Dysfunction of the sympathetic nervous system underlies a number of myocardial disorders. Positron emission tomography (PET) offers a way of assessing receptor function non-invasively in humans, but there are no PET radioligands for assessing myocardial alpha-adrenoceptors. GB67, a structural and pharmacological analogue of the alpha 1-adrenoceptor antagonist prazosin, was labelled with positron-emitting carbon-11 (t1/2 = 20.4 min) by 11C-methylation of N-desmethylamido-GB67 (GB99). [11C]GB67 was injected intravenously into conscious rats. Serial arterial blood samples were taken. Rats were killed and tissues removed to determine radioactivity. The percentages of unchanged [11C]GB67 and its radioactive metabolites in plasma and tissues were assessed by HPLC. Plasma clearance of radioactivity was rapid. Myocardial uptake was maximal at 1-2 min and decreased slowly during 60 min. Predosing with adrenoceptor antagonists demonstrated selectivity for myocardial alpha 1-adrenoceptors. GB67 and prazosin blocked uptake of radioactivity; the non-selective antagonist, phentolamine, partially blocked uptake; the alpha 2-adrenoceptor antagonist, RX 821002, only blocked uptake at high dose and the beta-adrenoceptor antagonist, CGP 12177, had no effect. Additionally, injection of prazosin at 20 min after radioligand displaced radioactivity. In vivo competition curves obtained by injecting [11C]GB67 with varying amounts of either unlabelled GB67 or its precursor GB99 were fitted to a competitive binding model to provide estimates of the maximum number of binding sites (Bmax) and half saturation doses (K) for myocardium. Assuming a tissue protein content of 10%, the values of Bmax [approximately 13 pmol.(g tissue)-1[ were similar to those ]50-170 fmol.(mg protein)-1] reported for myocardial alpha 1-adrenoceptors assessed in vitro. Both GB67 and its precursor GB99 had high affinity for alpha 1-adrenoceptors [KGB67 = 1.5 nmol.(kg body weight)-1, KGB99 = 4.8 nmol.(kg body weight)-1]. HPLC demonstrated four radioactive metabolites in plasma. [11C]GB67 was 80% of the radioactivity at 5 min and 50% at 45 min. No radioactive metabolites were detected in myocardium up to 60 min after injection. [11C]GB67 was assessed in two male human volunteers. PET demonstrated high myocardial uptake. The profile of radioactive metabolites in plasma was comparable to that in the rat, although metabolism was slower in humans. Thus, [11C]GB67 is a promising radioligand for assessing alpha 1-adrenoceptors in human myocardium with PET.