BACKGROUND: Fluorouracil is widely used for chemotherapy of gastrointestinal cancer, but response rates are poor. Eniluracil is being developed as an inactivator of dihydropyrimidine dehydrogenase, the enzyme that brings about first-pass degradation of fluorouracil. We studied the mechanism of action of eniluracil by measuring with positron emission tomography (PET) the effect of eniluracil on tumour and normal-tissue pharmacokinetics of fluorine-18-labelled fluorouracil. METHODS: Six patients with advanced gastrointestinal cancers were studied. PET scanning was done after injection of oxygen-15-labelled water to assess tissue blood flow, followed by 1 mg/m2 18F-fluorouracil. We compared the pharmacokinetics of 18F-fluorouracil when the patients had not received eniluracil, during a 4-day course of oral eniluracil, and during a 28-day course of oral fluorouracil plus eniluracil. FINDINGS: In eniluracil-naïve patients, 18F-fluorouracil localised more strongly (mean 0.0234% [SE 0.0019] of injected activity per mL tissue at 11 min) in liver than in tumours (0.0032% [0.0004]). There was substantial inhibition, after eniluracil administration, of radiotracer uptake and retention in normal liver (mean area under the time versus radioactivity curve 0.927 [SE 0.086] vs 1.857 [0.169] m2 mL(-1) s) and kidneys (1.096 [0.048] vs 5.043 [0.915] m2 mL(-1) s). There was also an increase in plasma uracil and unmetabolised 18F-fluorouracil and an increase in the radiotracer half-life in tumours (2.3 h to >4.0 h). INTERPRETATION: Two events strongly suggested increased exposure of 18F-fluorouracil and its anabolites in the tumours, consistent with the inactivation of dihydropyrimidine dehydrogenase: a selective decrease in radiotracer exposure in normal liver and kidneys compared with tumours; and an increase in radiotracer half-life in tumours.
BACKGROUND:Fluorouracil is widely used for chemotherapy of gastrointestinal cancer, but response rates are poor. Eniluracil is being developed as an inactivator of dihydropyrimidine dehydrogenase, the enzyme that brings about first-pass degradation of fluorouracil. We studied the mechanism of action of eniluracil by measuring with positron emission tomography (PET) the effect of eniluracil on tumour and normal-tissue pharmacokinetics of fluorine-18-labelled fluorouracil. METHODS: Six patients with advanced gastrointestinal cancers were studied. PET scanning was done after injection of oxygen-15-labelled water to assess tissue blood flow, followed by 1 mg/m2 18F-fluorouracil. We compared the pharmacokinetics of 18F-fluorouracil when the patients had not received eniluracil, during a 4-day course of oral eniluracil, and during a 28-day course of oral fluorouracil plus eniluracil. FINDINGS: In eniluracil-naïve patients, 18F-fluorouracil localised more strongly (mean 0.0234% [SE 0.0019] of injected activity per mL tissue at 11 min) in liver than in tumours (0.0032% [0.0004]). There was substantial inhibition, after eniluracil administration, of radiotracer uptake and retention in normal liver (mean area under the time versus radioactivity curve 0.927 [SE 0.086] vs 1.857 [0.169] m2 mL(-1) s) and kidneys (1.096 [0.048] vs 5.043 [0.915] m2 mL(-1) s). There was also an increase in plasma uracil and unmetabolised 18F-fluorouracil and an increase in the radiotracer half-life in tumours (2.3 h to >4.0 h). INTERPRETATION: Two events strongly suggested increased exposure of 18F-fluorouracil and its anabolites in the tumours, consistent with the inactivation of dihydropyrimidine dehydrogenase: a selective decrease in radiotracer exposure in normal liver and kidneys compared with tumours; and an increase in radiotracer half-life in tumours.
Authors: Eric O Aboagye; Fiona J Gilbert; Ian N Fleming; Ambros J Beer; Vincent J Cunningham; Paul K Marsden; Dimitris Visvikis; Antony D Gee; Ashley M Groves; Laura M Kenny; Gary J Cook; Paul E Kinahan; Melvyn Myers; Larry Clarke Journal: Eur Radiol Date: 2012-04-04 Impact factor: 5.315