Monitoring HSVtk suicide gene therapy: the role of [18F]FHPG membrane transport

Favourable pharmacokinetics of the prodrug are essential for successful HSVtk/ganciclovir (GCV) suicide gene therapy. [F-18] FHPG PET might be a suitable technique to assess the pharmacokinetics of the prodrug GCV noninvasively, provided that [F-18] FHPG mimics the behaviour of GCV. Since membrane transport is an important aspect of the pharmacokinetics of the prodrug, we investigated the cellular uptake mechanism of [F-18] FHPG in an HSVtk expressing C6 rat glioma cell line and in tumour- bearing rats. The nucleoside transport inhibitors dipyridamol, NBMPR and 2- chloroadenosine did not significantly affect the [F-18] FHPG uptake in vitro. Thymidine and uridine significantly decreased [F-18] FHPG uptake by 84 and 58%, respectively, but an enzyme assay revealed that this decline was due to inhibition of the HSVtk enzyme rather than membrane transport. Nucleobase transport inhibitors, thymine and adenine, caused a 58 and 55% decline in tracer uptake, respectively. In vivo, the ratio of [F-18] FHPG uptake in C6tk and C6 tumours decreased from 3.070.5 to 1.070.2 after infusion of adenine. Thus, in our tumour model, [F-18] FHPG transport exclusively occurred via purine nucleobase transport. In this respect, FHPG does not resemble GCV, which is predominantly taken up via the nucleoside transporter, but rather acyclovir, which is also taken up via the purine nucleobase carrier

Total 18F-dopa PET tumour uptake reflects metabolic endocrine tumour activity in patients with a carcinoid tumour

Positron emission tomography (PET) using 6-[(18)F]fluoro-L-dihydroxyphenylalanine ((18)F-dopa) has an excellent sensitivity to detect carcinoid tumour lesions. (18)F-dopa tumour uptake and the levels of biochemical tumour markers are mediated by tumour endocrine metabolic activity. We evaluated whether total (18)F-dopa tumour uptake on PET, defined as whole-body metabolic tumour burden (WBMTB), reflects tumour load per patient, as measured with tumour markers. Seventy-seven consecutive carcinoid patients who underwent an (18)F-dopa PET scan in two previously published studies were analysed. For all tumour lesions mean standardised uptake values (SUVs) at 40% of the maximal SUV and tumour volume on (18)F-dopa PET were determined and multiplied to calculate a metabolic burden per lesion. WBMTB was the sum of the metabolic burden of all individual lesions per patient. The 24-h urinary serotonin, urine and plasma 5-hydroxindoleacetic acid (5-HIAA), catecholamines (nor)epinephrine, dopamine and their metabolites, measured in urine and plasma, and serum chromogranin A served as tumour markers. All but 1 were evaluable for WBMTB; 74 patients had metastatic disease. (18)F-dopa PET detected 979 lesions. SUV(max) on (18)F-dopa PET varied up to 29-fold between individual lesions within the same patients. WBMTB correlated with urinary serotonin (r = 0.51) and urinary and plasma 5-HIAA (r = 0.78 and 0.66). WBMTB also correlated with urinary norepinephrine, epinephrine, dopamine and plasma dopamine, but not with serum chromogranin A. Tumour load per patient measured with (18)F-dopa PET correlates with tumour markers of the serotonin and catecholamine pathway in urine and plasma in carcinoid patients, reflecting metabolic tumour activity

Trumpet recital

Giuseppe TorelliCharles ChaynesGeorges EnescoJean RivierJoseph TurrinDigital audio of these performances is not yet available. You may submit a request for these recordings to be digitized and made available at this site within 10 work days at http://lib.asu.edu/music/services/perfdigitizeform?identifier=1989/12-2A&title=Trumpet+recita

Drug development, radiolabelled drugs and PET

Positron emission tomography (PET) provides noninvasive in vivo quantitative pharmacokinetic and pharmacodynamic information on novel and established drugs. Because only very low amounts of the (potential) drug have to be administered, far below toxicity levels, human studies can be carried out even before the drug is entered in phase I studies. Such studies can provide cost-effective predictive toxicology data and information on the metabolism and mode of action of drugs. PET is also very useful in the study of the metabolic consequences of gene expression or gene defects, In the last decade, several models using genetically engineered small animals have been developed. The study of these animals with high-resolution small animal PET cameras provides new opportunities in drug development. Especially valuable is the contribution of PET in bridging the gap between molecular biology, basic pathology and the design of a new generation of drugs