Positron emission tomography with 5-hydroxytryprophan in neuroendocrine tumors.

PURPOSE: Carcinoid tumors, especially those of midgut origin, produce serotonin via the precursors tryptophan and 5-hydroxytryptophan (5-HTP). We have evaluated the usefulness of positron emission tomography (PET) with carbon-11-labeled 5-HTP in the diagnosis and treatment follow-up evaluation of patients with neuroendocrine tumors. PATIENTS AND METHODS: PET using 11C-labeled 5-HTP was compared with computed tomography (CT) in 18 patients (14 midgut, one foregut, one hindgut carcinoid, and two endocrine pancreatic tumors [EPT]). In addition, 10 of 18 patients were monitored with PET examinations during treatment. RESULTS: All 18 patients, including two with normal urinary 5-hydroxyindole acetic acid (U-5-HIAA), had increased uptake of 11C-labeled 5-HTP in tumorous tissue as compared with normal tissue. Liver metastases, as well as lymph node, pleural, and skeletal metastases, showed enhanced 5-HTP uptake and PET could detect more lesions than CT in 10 patients and equal numbers in the others. Tumor visibility was better for PET than for CT due to the high and selective uptake of 5-HTP with a high tumor-to-background ratio. Binding studies indicated an irreversible trapping of 5-HTP in the tumors. Linear regression analyses showed a clear correlation (r = .907) between changes in U-5-HIAA and changes in the transport rate constant for 5-HTP during treatment. CONCLUSION: PET with 11C-labeled 5-HTP demonstrated high uptake in neuroendocrine gastrointestinal tumors and thereby allowed improved visualization compared with CT. The in vivo data on regional tumor metabolism, as expressed in 11C-5-HTP uptake and transport rate, provided additional information over conventional radiologic techniques. The close correlation between the changes in 11C-5-HTP transport rate and U-HIAA during medical treatment indicates the potential of 11C-5-HTP-PET as a means to monitor therapy.

Tacrine restores cholinergic nicotinic receptors and glucose metabolism in Alzheimer patients as visualized by positron emission tomography.

Three patients with Alzheimer's disease, a 68-year-old woman with mild dementia and 2 men (aged 64 and 72 years) with moderate dementia were treated orally with the cholinesterase inhibitor tacrine (tetrahydroaminoacridine), 80 mg daily, for several months. The patients were investigated using positron emission tomography (PET) prior to, and after 3 weeks and 3 months of treatment. The PET studies involved a multi-tracer system consisting of [18F]-fluoro-deoxy-glucose (18F-FDG) (tracer for glucose metabolism); 11C-butanol (cerebral blood flow) and (S)(-)- and (R)(+)-[N-11C-methyl]-nicotine (nicotinic receptors; cholinergic neural activity). Tacrine treatment increased the uptake of 11C-nicotine to the brain. Significant reduced difference in uptake between the two enantiomers (S)(-)- and (R)(+)11C-nicotine was observed in the frontal and temporal cortices after tacrine treatment in all three patients. The kinetic analysis indicated increased binding of (S)(-)11C-nicotine in brain compatible with a restoration of nicotinic cholinergic receptors. The most pronounced effect was observed after 3 weeks and 3 months treatment in the patient with mild dementia. An increase in cerebral glucose utilization was found in the 68-year-old patient with mild dementia but also slightly in the 64-year-old man with moderate dementia when treated with tacrine for 3 months. Tacrine administration did not affect cerebral blood flow. The PET data obtained after 3 weeks of tacrine treatment was paralleled by improvement in neuropsychological performance. This study shows in vivo by PET neurochemical effects induced in brain by treatment with tacrine to Alzheimer patients. Intervention with tacrine in the early course of the disease might be necessary for clinical improvement.

In vivo demonstration of enzyme activity in endocrine pancreatic tumors: decarboxylation of carbon-11-DOPA to carbon-11-dopamine.

METHODS: We used PET to characterize the uptake and decarboxylation of 11C-L-DOPA in vivo in two patients with endocrine pancreatic tumors: one glucagonoma and one gastrinoma. RESULTS: With L-DOPA labeled with 11C in the beta position, in which the radioactive label follows the molecule through decarboxylation to dopamine, significant uptake was observed in the tumors. With L-DOPA labeled in the carboxyl group, in which the label is rapidly eliminated from the tissue as 11CO2 if decarboxylation takes place, an almost complete lack of uptake is noted. CONCLUSION: This study shows that, using selective position labeling, an in vivo action of enzymatic activity can be observed with PET and that significant decarboxylation occurs in the tested endocrine pancreatic tumors. Also, marked retention of radioactivity occurs after treatment with somatostatin analogs. It is hypothesized that this is a reflection of a reduction of exocytosis which is induced by this treatment.

In vitro positron emission tomography (PET): use of positron emission tracers in functional imaging in living brain slices.

Positron-emitting radionuclides have short half-lives and high radiation energies compared with radioisotopes generally used in biomedical research. We examined the possibility of applying positron emitter-labeled compounds to functional imaging in brain slices kept viable in an oxygenated buffer solution. Brain slices (300 microns thick) containing the striatum were incubated with positron emitter-labeled tracers for 30-45 min. The slices were then rinsed and placed on the bottom of a Plexiglas chamber filled with oxygenated Krebs-Ringer solution. The bottom of the chamber consisted of a thin polypropylene film to allow good penetration of beta+ particles from the brain slices. The chamber was placed on a storage phosphor screen, which has a higher sensitivity and a wider dynamic range than X-ray films. After an exposure period of 15-60 min, the screen was scanned by the analyzer and radioactivity images of brain slices were obtained within 20 min. We succeeded in obtaining quantitative images of (1) [18F]fluorodeoxyglucose uptake, (2) dopamine D2 receptor binding, (3) dopa-decarboxylase activity, and (4) release of [11C]dopamine preloaded as L-[11C]DOPA in the brain slice preparation. These results demonstrate that positron emitter-labeled tracers in combination with storage phosphor screens are useful for functional imaging of living brain slices as a novel neuroscience technique.

Assessment of dopamine and its metabolites in the intracellular and extracellular compartments of the rat striatum after peripheral administration of L-[11C]dopa.

Success in the synthesis of L-3,4-[beta-11C]dihydroxyphenylalanine (L-[11C]DOPA) and its application to positron emission tomography encouraged us to perform radioactive metabolite analyses in rats in an early phase after peripheral injection of L-[11C]DOPA. Following intravenous injection of [11C]DOPA, the radioactivity associated with DOPA and its metabolites was determined in the striatum after decapitation and in striatal extracellular fluid using in vivo brain microdialysis. Without pretreatment, 70-80% of 11C-radioactivity taken up into the striatum was associated with acidic metabolites of dopamine (DA) from 2 to 30 min after administration of L-[11C]DOPA with or without 300 micrograms/kg of unlabelled L-DOPA. In contrast, 80-90% of 11C-radioactivity in the striatum was associated with DOPA and DA after pretreatment with benserazide (25 mg/kg, i.p.) followed by administration of L-[11C]DOPA with or without unlabelled L-DOPA. The radioactivity in the DOPA fraction decreased with time (from 35% of 11C-radioactivity in the striatum at 5 min to 10% at 30 min), but that in the DA fraction increased (from 57% to 68%). The 11C-radioactivity in the extracellular fluid determined by brain microdialysis was less than 0.4% of that in the whole striatum and no radioactivity was present in the DA fraction. These results suggest that, in an early phase after administration of L-[11C]DOPA, [11C]DA is the main metabolite and is localized exclusively in the intracellular compartment within this time frame.

Unilateral MPTP lesion in a rhesus monkey: effects on the striatal dopaminergic system measured in vivo with PET using various novel tracers.

We have produced in one monkey a unilateral lesion of the dopaminergic nigrostriatal pathway by slowly infusing 1-methyl-4-phenyl-1.2.3.6-tetrahydropyridine (MPTP) into the right internal carotid artery, resulting in contralateral hemiparkinsonism. This procedure was combined with a series of positron emission tomography scans before and after the lesion, using several dopaminergic tracers in parallel. We show that specific binding of [11C]nomifensine in the lesioned striatum disappears to a large extent (80-90%) as a result of the lesion, indicating a corresponding loss of striatal dopamine re-uptake binding sites and thus of the dopamine nerve terminal pool. The uptake of radioactivity in the striatum contralateral to the lesion remained unchanged. In parallel, an early increase in ipsilateral [11C]raclopride binding, indicating upregulation of dopamine D2 receptors, was seen following the presynaptic lesion. [11C]Deprenyl uptake, indicating monoamine oxidase type B enzyme concentration, did not change after the lesion.

Effect of 6R-L-erythro-5,6,7,8-tetrahydrobiopterin and infusion of L-tyrosine on the in vivo L-[beta-11C] DOPA disposition in the monkey brain.

The effect of 6R-L-erythro-5,6,7,8-tetrahydrobiopterin (6R-BH4) and L-tyrosine infusion on [11C]dopamine synthesis was analyzed in the striatum of Rhesus using positron emission tomography (PET). The rate for decarboxylation from L-[beta-11C]DOPA to [11C]dopamine was calculated using a graphical method with cerebellum as a reference region. Although the peripheral administration of 6R-BH4 at low dose (2 mg/kg) did not provide a significant increase in the rate of dopamine biosynthesis, a high dose of 6R-BH4 (20 mg/kg) induced an elevation of the rate. This 6R-BH4-induced elevation of the dopamine synthesis rate was further dose-dependently enhanced by the continuous infusion of L-tyrosine (0.2 and 1.0 mumol/min/kg). L-Tyrosine infusion with a rate of 1.0 mumol/min/kg caused an enhancement of the rate even during low dose administration of 6R-BH4 (2 mg/kg). L-Tyrosine infusion alone did not induce any elevation of the dopamine biosynthesis rate. The analysis of plasma indicated that the metabolic ratios of L-[beta-11C]DOPA to each metabolite were not affected by 6R-BH4 and/or L-tyrosine infusion. The results suggest that the low dose loading of tyrosine facilitates the activity of 6R-BH4 on the presynaptic dopamine biosynthesis, and also that the combined effects can be monitored by PET using L-[beta-11C]DOPA as a biochemical probe.

Demonstration of [11C] 5-hydroxy-L-tryptophan uptake and decarboxylation in carcinoid tumors by specific positioning labeling in positron emission tomography.

In three patients with carcinoid liver and/or lymph node metastases, we studied the process of tumor tracer uptake and decarboxylation by means of positron emission tomography (PET) using 5-hydroxy-L-tryptophan (5-HTP) 11C-labeled in the beta-position (HTP) and later the same day with 5-HTP 11C-labeled in the carboxyl group (HTC). With HTP, in which the 11C-label follows the molecule through decarboxylation to form 11C-serotonin, a high tumor accumulation of the tracer was found. With HTC, in which the label is rapidly eliminated from the tissues as 11CO2 if decarboxylation takes place, there was virtually no uptake by the tumors. By utilizing data from PET scanning with both tracers, we could quantify the decarboxylation rate and tissue accumulation of [11C]-serotonin and hence the enzymatic action of aromatic amino acid decarboxylase.

Determination of 5-hydroxy-L-[beta-11C]tryptophan and its in vivo-formed radiolabeled metabolites in brain tissue using high performance liquid chromatography: a study supporting radiotracer kinetics obtained with positron emission tomography.

A high performance liquid chromatographic system was developed for separation of 11C-labeled 5-hydroxy-L-tryptophan ([11C]HTP) and in vivo formed radiolabeled metabolites in rat brain tissue. Analysis of brain homogenate revealed that the main part of the radioactivity was associated with 11C-labeled 5-hydroxyindole-3-acetic acid after intravenous injection of [11C]HTP to the rat. The serotonin synthesis rate in the brain was calculated and closely correlated to the serotonin synthesis rate in monkey and human measured using positron emission tomography.

Modulation of organ uptake of 11C-labelled L-DOPA.

The present study was undertaken to investigate if pretreatment with pharmacological agents could change the organ uptake of 11C-labelled L-DOPA, and especially if the urinary excretion could be decreased. L-[beta-11C]DOPA was injected IV into unanesthetized Sprague-Dawley rats. After 20 min the rats were decapitated and organs taken out for radioactivity measurements. The uptake in the organs was investigated in animals only given the tracer, and in animals pretreated with drugs such as decarboxylase inhibitors carbidopa and benserazide as well as the monoamine oxidase inhibitors deprenyl, clorgyline, and the COMT inhibitor OR-486. A marked decrease in the urinary radioactivity was observed after carbidopa and benserazide administration. HPLC analysis revealed that under native conditions the major part of urinary radioactivity existed as dopamine, which was eliminated by the decarboxylase inhibitors. After pretreatment with the COMT inhibitor OR-486, the radioactivity uptake in the pancreas increased fourfold as compared to non-treated animals. HPLC analysis showed that this correlated with a marked increase in radiolabelled DOPAC. In the other organs and with the other drugs, only small effects were observed. With L-[beta-11C]fluoroDOPA as a tracer, similar results were observed although the increase in the pancreas by OR-486 had a lower magnitude. These studies suggest that it might be possible to improve the diagnostic ratio of L-[beta-11C]DOPA or L-[18F]fluoroDOPA in whole-body PET studies by pretreating the patient with decarboxylase inhibitor for reducing the urinary excretion and potentially increase the target organ uptake by COMT inhibition.

Methodological aspects for in vitro characterization of receptor binding using 11C-labeled receptor ligands: a detailed study with the benzodiazepine receptor antagonist [11C]Ro 15-1788.

As a complement to in vivo studies with positron emission tomography (PET), it is desirable to perform in vitro characterization of newly developed 11C tracers. In this report we describe the technique for determination of receptor-ligand kinetics utilizing ligands labeled with the short-lived radionuclide 11C. The limitations and advantages are discussed. The benzodiazepine antagonist [11C]Ro 15-1788 was used as a model substance, and the use of storage phosphor plates for quantification of radioactivity was validated. Storage phosphor plates showed an excellent linear range (approximately 10[3]) and acceptable resolution (approximately 0.5 mm). Receptor-ligand kinetics, including depletion, association and dissociation, saturation and displacement were evaluated with good results through the use of short-lived radiotracers and storage phosphor plates.

Uptake and utilization of [beta-11C]5-hydroxytryptophan in human brain studied by positron emission tomography.

The immediate precursor in the serotonin synthetic route, 5-hydroxytryptophan (5-HTP), labeled with 11C in the beta position, has become available for studies using positron emission tomography (PET) to examine serotonin formation in human brain. Normalized uptake and intracerebral utilization of tracer amounts of [beta-11C]5-HTP were studied twice in six healthy male volunteers, three of them before and after pharmacological pretreatments. The kinetic model defines regional utilization as the relative regional radioactivity accumulation rate. Repeat studies showed good reproducibility. Pretreatments with benserazide, p-chlorophenylalanine (PCPA), and unlabeled 5-HTP all significantly increased uptake of [beta-11C]5-HTP. The utilization rates in both striatal and frontal cortex were higher than those in the surrounding brain, indicating that PET studies using [beta-11C]5-HTP as a ligand quantitate selective processes in the utilization of 5-HTP. We tentatively interpret uptake and utilization as a measure of brain serotonin turnover, the selectivity of which was shown by pharmacological interventions in vivo.

Liquid chromatographic analysis of brain homogenates and microdialysates for the quantification of L-[beta-11C]DOPA and its metabolites for the validation of positron emission tomography studies.

The clinical use of positron emission tomography, PET, with selected radiolabelled tracer molecules visualizing and quantitating physiological processes in the tissue relies in many situations on compartmental models for the interpretation of the radiosignal. Validation of such models must, therefore, include chromatographic analysis of the radioactivity composition of the signal. Rapid and sensitive liquid chromatographic methods amenable for automation for the analysis of [11C] labelled L-DOPA and its metabolites were therefore developed and validated for the quantitation of radioactivity composition in rat brain microdialysates as well as homogenates. Analysis included a simple isolation step, separation using reversed phase liquid chromatography with radiometric detection and permitted assay following tracer doses with an analysis time of 15 min. The analysis of radioactivity composition in the rat striatum showed that peripherally formed O-methyl L-DOPA constituted less than 20% of the radioactivity 40 min after injection of L-[beta-11C]DOPA. In the extracellular space the main component was [11C]-homovanillic acid which increased with time indicating rapid formation but slow elimination. The cumulation of radioactivity in the striatum corresponded to the radioactivity signal of dopamine and derived metabolites. The formation rate of dopamine in the rat corresponded closely to the utilization rate in the striatum of monkey and man measured with PET. This indicated that the rate constants measured with PET correlates well to the dopamine synthesis rate.

Determination of clenbuterol residues in bovine urine by optical immunobiosensor assay.

Clenbuterol (CBL) is an orally active beta2-adrenoceptor agonist which has been used in veterinary medicine as a broncodilator and an agent of uterine relaxation. It has however become better known as a drug used illegally to promote growth in farm animals. A rapid and sensitive biosensor assay was developed to detect CBL residues in bovine urine. The method involved a simple extraction procedure using tert-butyl methyl ether followed by analysis on the biosensor with results obtained against a buffer calibration curve. The assay allowed up to 88 samples to be analyzed per working day, with each cycle on the biosensor taking approximately 7 min to complete. The limit of detection (LOD) was determined as 0.27 ng/mL using 20 EU reference blank urine samples. The intra-assay Sr ranged from 4.7-7.6% for 3 control samples while the interassay Sr ranged from 9.2-12.7%. The recovery was found to be approximately 95%. A series of incurred urine samples were assayed and the results compared by Enzyme immunoassay (EIA), radio-immunoassay (RIA), and gas chromatography/mass spectrometry (GC/MS) analysis. Urine samples taken from local abattoirs were also analyzed by the biosensor method and by EIA analysis. The antibody used in the biosensor test exhibited high cross reactivity with at least 7 other beta-agonists allowing detection of these compounds at less than 1 ng/mL in bovine urine.

Brain kinetics of L-[beta-11C]dopa in humans studied by positron emission tomography.

The in vivo dopamine precursor L-3,4-dihydroxyphenylalanine (L-DOPA) labelled with 11C in the beta position has been used for positron emission tomography studies of L-DOPA utilization in the brain. The brain uptake and kinetics of L-[11C]DOPA-derived radioactivity were studied in healthy male volunteers, and the specific utilization, i.e. decarboxylation rate of L-[11C]DOPA in different brain areas, was quantified using a brain region devoid of specific L-[11C]DOPA utilization as reference. Total uptake of L-[11C]DOPA-derived radioactivity measured in the brain varied two- to three-fold between subjects, with highest radioactivity in the striatal region. Specific utilization of L-[11C]DOPA radioactivity in the striatal region and in the prefrontal cortex varied twofold between subjects. No specific utilization was observed in other regions of the brain. The uptake of radioactivity in the brain increased dose-dependently with the simultaneous administration of unlabelled L-DOPA up to 10 mg. On the other hand, a decrease in brain radioactivity uptake was measured after pretreatment with 1 mg/kg oral L-DOPA, indicating competition for transport across the blood-brain barrier. Benserazide 0.5 mg/kg orally increased somewhat the radioactivity uptake to the brain. None of these pharmacological perturbations demonstrated any clearcut effect on specific utilization of L-[11C]DOPA. Thus, 11C-labelled L-DOPA is introduced as an alternative to the well-established L-6-[18F]fluoro-DOPA methodology in clinical studies on brain L-DOPA uptake and dopamine synthesis.

Regional brain kinetics of 6-fluoro-(beta-11C)-L-dopa and (beta-11C)-L-dopa following COMT inhibition. A study in vivo using positron emission tomography.

The regional brain kinetics of (beta-11C)-L-dopa and 6-fluoro-(beta-11C)-L-dopa was measured in six Rhesus monkeys using positron emission tomography (PET). Radioactivity accumulated specifically in the striatal region and the increase in L-dopa-derived radioactivity utilization with time was calculated using surrounding brain as a reference area, this being devoid of dopaminergic activity. The rate constant for selective striatal utilization i.e. grossly decarboxylation was 0.0110 +/- 0.0007 (S.D) and 0.0057 +/- 0.0006 min-1 for (beta-11C)-L-dopa and 6-fluoro-(beta-11C)-L-dopa, respectively. After pretreatment of the monkeys with the peripherally and centrally active catecholamine-O-methyl transferase (COMT) inhibitor Ro 40-7592 10 mg/kg, the decarboxylation rate remained unchanged (0.0112 +/- 0.0015 min-1) for (beta-11C)-L-dopa, whereas an increase in rate was measured for 6-fluoro-(beta-11C)-L-dopa (0.0092 +/- 0.0015 min-1). Differences in the distribution of radiolabelled metabolites i.e. the corresponding O-methyl-L-dopa in the reference area is most probably the reason for the difference in calculated decarboxylation rate seen between the radiotracers. The higher decarboxylation rate measured for 6-fluoro-(beta-11C)-L-dopa after blockade of COMT shows that the radiolabelled metabolites i.e. 6-fluoro-O-methyl-(beta-11C)-L-dopa significantly contributes to background radioactivity.

Cerebral uptake and utilization of therapeutic [beta-11C]-L-DOPA in Parkinson's disease measured by positron emission tomography. Relations to motor response.

Cerebral uptake and utilization of levodopa was measured in eight patients with idiopathic Parkinson's disease (PD) by [beta-11C]-L-DOPA and positron emission tomography (PET). By adding pharmacological doses of unlabelled levodopa to the radioactive solution it was possible to evaluate the clinical effect simultaneously with the cerebral kinetics of the drug. Additionally, in two of the patients with advanced PD, investigations with the dopamine re-uptake blocker [11C]-(+)-nomifensine and PET were carried out to get a measure of the density of striatal dopaminergic nerve-terminals. The brain uptake of [beta-11C]-L-DOPA was inversely correlated to the sum of large neutral amino acids in plasma. In the eight PD patients studied with [beta-11C]-L-DOPA striatal k3, which reflects the ability for striatal tissue to decarboxylate the tracer by the action of aromatic L-amino acid decarboxylase (AADC), was decreased 35% compared to healthy subjects. It was demonstrated that, in the patients with advanced PD and motor fluctuations on oral L-DOPA medication, reversal of parkinsonian symptoms occurred at very low striatal tissue dopamine concentrations. In the two very advanced patients studied with [11C]-(+)-nomifensine the striatal binding of the tracer was 50% reduced.

Estimation of regional cerebral utilization of [11C]-L-3,4-dihydroxy-phenylalanine (DOPA) in the primate by positron emission tomography.

The intracerebral kinetics of [11C]-labelled L-3,4-dihydroxyphenylalanine, L-DOPA, was investigated in rhesus monkeys by positron emission tomography (PET). Through the labelling of the L-DOPA molecule in different positions and observation of a series of pharmacological challenges it was possible to establish that the kinetic conversion of the radiotracer in the striatum represents the process of decarboxylation to [11C]-labelled dopamine. The rate constant for this process can be estimated using a two-compartment model. The use of [11C]-L-DOPA and PET will thus provide a possibility for in vivo studies of blood-brain barrier transport of the amino acid as well as for the estimation of the ability for brain tissue to decarboxylate the tracer by the action of aromatic L-amino acid decarboxylase.