IPdR: a novel oral radiosensitizer.

IPdR (5-iodo-2-pyrimidinone-2'-deoxyribose) is a novel orally available, halogenated thymidine (TdR) analog and is a potential radiosensitizer for use in human tumors, such as rectal, pancreas, sarcoma and glioma tumors. IPdR is a prodrug that is efficiently converted to IUdR (5-iodo-2'-deoxyuridine), an intravenous radiosensitizer by a hepatic aldehyde oxidase, resulting in high IPdR and IUdR plasma levels in mice for > or = 1 h after oral IPdR. Athymic mice tolerated oral IPdR to doses up to 1500 mg/kg/day t.i.d. for 6 - 14 days without significant systemic toxicities. A number of in vivo preclinical studies have demonstrated that IPdR is a superior radiosensitizer compared with IUdR given as a continuous infusion in terms of safety and efficacy with a significantly lower toxicity profile, including gastrointestinal and hematologic side effects. A preclinical study has shown that IPdR is effective in inducing human colon cancer xenograft radiosensitization in drug-resistant DNA mismatch repair-proficient and -deficient tumor models, as well as in human globlastoma xenograft. In anticipation of performing a clinical Phase I trial in humans, investigators also studied the drug pharmacokinetics and host toxicities in two non-rodent, animal species during a 14-day treatment course. Dose-limiting systemic toxicities (diarrhea, emesis, weight loss and decreased motor activity) were observed in ferrets receiving IPdR at 1500 mg/kg/day on a 14-day schedule that were not found previously in athymic mice. Recently, a once-daily IPdR dosing up to 2000/mg/kg for 28 days in Fischer-344 rats showed reversible mild-to-moderate systemic toxicities without any severe or life-threatening toxicities. However, in all preclinical toxicity studies so far, no significant hematologic, biochemical or histopathologic changes have been found. Hepatic aldehyde oxidase activity was reduced in a dose-dependent fashion in the ferret liver, suggesting partial enzyme inactivation by this IPdwR schedule, but that is not found in Fischer-344 rats. The plasma pharmacokinetic profile in Rhesus monkeys showing biexponential clearance are similar to previously published data in athymic mice. In this paper, the authors review the development, mechanism of action, preclinical data and rationale for clinical studies.

Synthesis and evaluation of [18F] labeled pyrimidine nucleosides for positron emission tomography imaging of herpes simplex virus 1 thymidine kinase gene expression.

Synthesis of three novel 2'-deoxy-2'-[18F]fluoro-1-beta-D-arabinofuranosyluracil derivatives [18F]FPAU, [18F]FBrVAU, and [18F]FTMAU is reported. The compounds were synthesized by coupling of 1-bromo-2-deoxy-2-fluoro sugars with corresponding silylated uracil derivatives. In vitro cell uptake indicated that all three compounds are taken up selectively in RG2TK+ cells with negligible uptake in RG2 cells. The results indicate that [18F]FBrVAU and [18F]FTMAU have better uptake profiles in comparison to [18F]FPAU and have potential as PET probes for imaging HSV1-tk gene expression.

Preclinical study of the systemic toxicity and pharmacokinetics of 5-iodo-2-deoxypyrimidinone-2'-deoxyribose as a radiosensitizing prodrug in two, non-rodent animal species: implications for phase I study design.

We have demonstrated previously an improved therapeutic index for oral 5-iodo-2-deoxypyrimidinone-2'-deoxyribose (IPdR) compared with oral and continuous infusion of 5-iodo-2'-deoxyuridine (IUdR) as a radiosensitizing agent using three different human tumor xenografts in athymic mice. IPdR is a prodrug that is efficiently converted to IUdR by a hepatic aldehyde oxidase, resulting in high IPdR and IUdR plasma levels in mice for > or =1 h after p.o. IPdR. Athymic mice tolerated oral IPdR at up to 1500 mg/kg/day given four times per day for 6-14 days without significant systemic toxicities. In anticipation of an investigational new drug application for the first clinical Phase I and pharmacology study of oral IPdR in humans, we studied the drug pharmacokinetics and host toxicities in two non-rodent, animal species. For the IPdR systemic toxicity and toxicology study, twenty-four male or female ferrets were randomly assigned to four IPdR dosage groups receiving 0, 15, 150, and 1500 mg/kg/day by oral gavage x 14 days prior to sacrifice on study day 15. All ferrets survived the 14-day treatment. Ferrets receiving 1500 mg/kg/day showed observable systemic toxicities with diarrhea, emesis, weight loss, and decreased motor activity beginning at days 5-8 of the 14-day schedule. Overall, both male and female ferrets receiving IPdR at 1500 mg/kg/day experienced significant weight loss (9 and 19%, respectively) compared with controls after the 14-day treatment. No weight loss or other systemic toxicities were observed in other IPdR dosage groups. Grossly, no anatomical lesions were noted at complete necropsy, although liver weights were increased in both male and female ferrets in the two higher IPdR dosage groups. Histologically, IPdR-treated animals showed dose-dependent microscopic changes in liver consisting of minimal to moderate cytoplasmic vacuolation of hepatocytes, which either occurred in the periportal area (high dosage group) or diffusely throughout the liver (lower dosage groups). Female ferrets in the highest IPdR dose group also showed decreased kidney and uterus weights at autopsy without any associated histological changes. No histological changes were found in central nervous system tissues. No significant abnormalities in blood cell counts, liver function tests, kidney function tests, or urinalysis were noted. Hepatic aldehyde oxidase activity was decreased to approximately 50 and 30% of control ferrets in the two higher IPdR dosage groups, respectively, after the 14-day treatment period. The % IUdR-DNA incorporation in ferret bone marrow at the completion of IPdR treatment was < or =0.05% in the two lower dosage groups and approximately 2% in the 1500 mg/kg/day dosage group. The % IUdR-DNA in normal liver was < or =0.05% in all IPdR dosage groups. In a pharmacokinetic study in four Rhesus monkeys, we determined the plasma concentrations of IPdR after a single i.v. bolus of 50 mg/kg over 20 min. Using a two-compartment model to fit the plasma pharmacokinetic data, we found that IPdR was cleared in these non-human primates in a biexponential manner with an initial rapid distributive phase (mean T1/2alpha = 6.5 min), followed by an elimination phase with a mean T1/2 of 63 min. The mean maximum plasma concentration of IPdR was 124+/-43 microM with a mean total body clearance of 1.75+/-0.95 l/h/kg. IPdR was below detection (<0.5 microM) in the cerebrospinal fluid. We conclude that there are dose-limiting systemic toxicities to a 14-day schedule of p.o. IPdR at 1500 mg/kg/day in ferrets that were not found previously in athymic mice. However, no significant hematological, biochemical, or histopathological changes were found. Hepatic aldehyde oxidase activity was reduced in a dose-dependent in ferret liver, suggesting partial enzyme saturation by this IPdR schedule. The plasma pharmacokinetic profile in Rhesus monkeys showing biexponential clearance is similar to our published data in athymic mice. These data are being applied