Lack of toxicity of a STAT3 decoy oligonucleotide.

BACKGROUND: STAT3 overexpression has been detected in several cancers including head and neck squamous cell carcinoma (HNSCC). Previous studies using intratumoral administration of a STAT3 decoy oligonucleotide that abrogates STAT3-mediated gene transcription in preclinical cancer models have demonstrated antitumor efficacy. This study was conducted to observe the toxicity and biologic effects of the STAT3 decoy in a non-human primate model, in anticipation of initiating a clinical trial in HNSCC patients. METHODS: Three study groups (two monkeys/sex/group) were administered a single intramuscular injection of low dose of STAT3 decoy (0.8 mg total dose/monkey), high dose of STAT3 decoy (3.2 mg total dose/monkey) or vehicle control (PBS alone) on day 1 and necropsies were performed on days 2 and 15 (one monkey/sex/group/day). Low and high doses of the decoy were administered in the muscle in a volume of 0.9 ml. Tissue and blood were harvested for toxicology and biologic analyses. RESULTS: Upon observation, the STAT3 decoy-treated animals exhibited behavior that was similar to the vehicle control group. Individual animal body weights remained within 1% of pretreatment weights throughout the study. Hematological parameters were not significantly different between the control and the treatment groups. Clinical chemistry fluctuations were considered within normal limits and were not attributed to the STAT3 decoy. Assessment of complement activation breakdown product (Bb) levels demonstrated no activation of the alternative pathway of complement in any animal at any dose level. At necropsy, there were no gross or microscopic findings attributed to STAT3 decoy in any organ examined. STAT3 target gene expression at the injection site revealed decreased Bcl-X(L) and cyclin D1 expression levels in the animals treated with high dose of STAT3 decoy compared to the animals injected with low dose of STAT3 decoy or the vehicle as control. CONCLUSION: Based on these findings, the no-observable-adverse-effect-level (NOAEL) was greater than 3.2 mg/kg when administered as a single dose to male and female Cynomolgus monkeys. Plans are underway to test the safety and biologic effects of intratumoral administration of the STAT3 decoy in HNSCC patients.

Toxicology and pharmacokinetic study of orally administered 5-iodo-2-pyrimidinone-2'deoxyribose (IPdR) x 28 days in Fischer-344 rats: impact on the initial clinical phase I trial design of IPdR-mediated radiosensitization.

PURPOSE: A toxicology and pharmacokinetic study of orally administered (po) IPdR (5-3iodo-2-pyrimidinone-2'deoxyribose, NSC-726188) was performed in Fischer-344 rats using a once daily (qd) x 28 days dosing schedule as proposed for an initial phase I clinical trial of IPdR as a radiosensitizer. METHODS: For the toxicology assessment, 80 male and female rats (10/sex/dosage group) were randomly assigned to groups receiving either 0, 0.2, 1.0 or 2.0 g kg(-1)day(-1) of po IPdR x 28 days and one-half were observed to day 57 (recovery group). Animals were monitored for clinical signs during and following treatment with full necropsy of one-half of each dosage group at day 29 and 57. For the plasma pharmacokinetic assessment, 40 rats (10/sex/dosage group) were randomly assigned to groups receiving either 0.2 or 1.0 g kg(-1)day(-1) of po IPdR x 28 days with multiple blood samplings on days 1 and 28 and single blood sampling on days 8 and 15. RESULTS: No drug-related deaths occurred. Higher IPdR doses resulted in transient weight loss and transient decreased hemoglobins but had no effect on white cells or platelets. Complete serum chemistry evaluation showed transient mild decreases in total protein, alkaline phosphatase, and serum globulin. Necropsy evaluation at day 29 showed minimal to mild histopathologic changes in bone marrow, lymph nodes and liver; all reversed by day 59. There were no sex-dependent differences in plasma pharmacokinetics of IPdR noted and the absorption and elimination kinetics of IPdR were found to be linear over the dose range studied. CONCLUSIONS: A once-daily dosing schedule of po IPdR for 28 days with doses up to 2.0 g kg(-1)day(-1) appeared to be well tolerated in Fischer-344 rats. Drug-related weight loss and microscopic changes in bone marrow, lymph nodes and liver were observed. These changes were all reversed by day 57. IPdR disposition was linear over the dose range used. However, based on day 28 kinetics it appears that IPdR elimination is enhanced following repeated administration. These toxicology and pharmacokinetic data were used when considering the design of our initial phase I trial of po IPdR as a clinical radiosensitizer.

Chiral high-performance liquid chromatographic analysis of the enantiomers of XK469, a new antitumor agent, in plasma and urine.

XK469 (NSC697887), (+/-)-2-[4-(7-Chloro-2-quinoxaliny)oxy]-phenoxy propionic acid, an analog of the herbicide Assure(R), which possesses antitumor activity, especially against murine solid tumors and human xenografts, has recently been found to be the first topoisomerase II beta poison. Both R(+) and S(-) isomers are cytotoxic, although the R-isomer is more potent. A chiral high-performance liquid chromatography (HPLC) assay that utilizes Chirobiotic T column for the measurement of enantiomers of XK469 in plasma has been developed with a limit of quantitation (LOQ) of 0.2 microg/ml using a 0.2 ml plasma sample. Chloroqinoxaline sulfonamide (CQS) was used as the internal standard and the assay has been validated in rat plasma. The within-run coefficient of variations (CVs) were 5.9, 5.0, and 3.1% for the S-isomer and 8.1, 4.2, 6.4% for R(+)-XK469 at 0.2, 1, and 2 microg/ml, respectively. The between-run CVs were 10.5, 5.3, and 1.9% for S(-)- and 10.9, 6.3, and 3.6% for R(+)-XK469. Using this chiral assay, a plasma concentration time data of R(+)-,S(-)-XK469 in a Fischer 344 rat receiving i.v. dosing of S(-)XK469 at 10 mg/kg was monitored. S(-)XK469 was found to be significantly converted to the R-enantiomer in circulation even when the S-enantiomer was administered. The predominant inversion from S(-)- to R(+)-XK469 was also observed in the mouse and dog plasma. In the rat, the plasma concentration-time profiles for both isomers follow two compartmental pharmacokinetics with the t(1/2 beta) for the R-enantiomer slightly longer and the clearance of the S-enantiomer higher than the R-enantiomer.