Carbonate and carbamate derivatives of 4-demethylpenclomedine as novel anticancer agents.

PURPOSE: The purpose of this investigation was to synthesize a series of carbonate and carbamate derivatives of 4-demethylpenclomedine (DM-PEN), the major plasma non-toxic metabolite of penclomedine (PEN) seen in patients. DM-PEN has been observed to be an active antitumor agent in mouse human xenograft tumor models and non-neurotoxic in a rat model, however, activity in intracranially implanted human glioma xenograft models have not been reported. The major goal was to identify derivatives that are active in brain tumors. METHODS: Derivatives were prepared from DM-PEN and evaluated in vivo against human U251 glioblastoma, D54 glioblastoma and MX-1 breast tumor xenografts and mammary tumor 16/C that were implanted in the mammary fat pad or intracranially (IC). RESULTS: Carbonate and carbamate derivatives were found to be superior to DM-PEN against IC growing human glioblastoma xenografts. CONCLUSION: The activity of the carbonates and carbamates against human tumor xenografts in vivo suggests consideration of these two series of derivatives of DM-PEN for clinical development.

Thiolo-, thiono- and dithiocarbonate and thiocarbamate derivatives of demethylpenclomedine as novel anticancer agents.

PURPOSE: The purpose of this investigation was to synthesize a series of thiolo-, thiono- and dithiocarbonate and thiocarbamate derivatives of 4-demethylpenclomedine (DM-PEN), the major plasma metabolite of penclomedine (PEN) in patients observed subsequently to be an active antitumor agent and non-neurotoxic in a rat model, in order to compare their antitumor activity with that of DM-PEN. METHODS: Derivatives were prepared from DM-PEN and evaluated in vivo against human MX-1 breast tumor xenografts implanted in the mammary fat pad, several of which were also evaluated against human brain tumor xenografts. RESULTS: Thiolocarbonate and thiocarbamate derivatives were found to be superior to DM-PEN against MX-1 tumor and modestly active against glioblastoma. CONCLUSION: The activity of the thiolocarbonates and thiocarbamates against human tumor xenografts in vivo suggests consideration of these two series of derivatives of DM-PEN for clinical development.

Comparative preclinical toxicology and pharmacology of isophosphoramide mustard, the active metabolite of ifosfamide.

BACKGROUND: Isophosphoramide mustard (IPM) is the cytotoxic alkylating metabolite of Ifosfamide (IFOS). IPM is being readied for a phase I clinical trial. In the present preclinical study, IPM was evaluated for usage in multidose intravenous (IV) infusion protocols. METHODS: Mice and dogs received IV IPM daily for 3 days. Single-day dosing-oral and IV-to mice, rats, and monkeys is also reviewed for comparison. Complete toxicology studies were completed in the mice and dogs. For mice, dogs and monkeys, IV pharmacokinetic studies were conducted and compared. RESULTS: For mice, the LD(10) for the 3-day IV schedule for IPM was calculated to be 119 mg/kg (with 95% confidence limits of 87-134 mg/kg) (combined sexes), and for adult male dogs the maximum tolerated dose (MTD) was 5 mg/kg. Pharmacokinetic studies in mice, dogs and monkeys were compared and projected to human dosing. For dogs that received 10 mg/kg of IPM, T(1/2beta) was 0.99 h, and clearance was constant (1.01 l/h/kg). IPM was detected from 0 h to 1.5 h after the 5 mg/kg dose and from 0 h to 2 h after the 10 mg/kg dose; none was detected after 2 h. The IV MTD in dogs was 5 mg/kg per day for 3 days. Renal tubular necrosis and bone marrow failure were the causes of death. Transient liver, renal and bone marrow toxicity and gastrointestinal dysfunction were seen at low doses (<5 mg/kg) in dogs. In mice (receiving 100 mg/kg IV) plasma concentrations disappeared in less than 1 h (T(1/2alpha) 2 min), with a clearance of 8.44 l/h/kg. For monkeys, the mean T(1/2) was 4.2 h. Median clearance was 1.65 l/h/kg and no IPM was detected 4 h after dosing. No potential IPM metabolites could be detected in any of the studies. In vitro, plasma protein bound 90% of IPM within 5 min of incubation. CONCLUSIONS: Predictions for human pharmacokinetic parameters and dosing are made from allometric analysis using the above three species. Data predicted an acceptable starting dose of 30 mg/m(2) with a clearance of 39.5 l/h, and a T(1/2) of 1 h 45 min for a 70-kg patient.

The alkylating agent penclomedine induces degeneration of purkinje cells in the rat cerebellum.

PURPOSE: Penclomedine (PEN), a multichlorinated alpha-picoline derivative which is metabolized to highly reactive alkylating species, was selected for clinical development due to its prominent activity against a wide range of human tumor xenografts when administered either parentally or orally. Its principal dose-limiting toxicity in preclinical and clinical studies has been neurocerebellar toxicity, which has been related to the magnitude of peak plasma PEN concentrations, but not to plasma concentrations of its putative principal alkylating metabolite, 4,o-demethylpenclomedine (DMPEN). These observation, as well as PEN's toxicologic, pharmacologic, and tissue distribution profiles, have suggested that the parent compound is primarily responsible for cerebellar toxicity. The studies described in this report were undertaken to characterize the neuropathology of PEN neurotoxicity, with a long-term goal of developing strategies to maximize its therapeutic index. DESIGN: Male Sprague-Dawley rats were treated with therapeutically relevant doses of PEN, orally and intraperitoneally (i.p.), on various administration schedules, and DMPEN administered i.p. The animals were monitored for neurotoxicity, and brain sections were examined for neuropathology, particularly Purkinje cell loss and neuronal injury. Brain sections were stained using standard histochemical techniques and immunostained with OX-42 to detect microglial cells that are activated following neuronal damage, and calbindin D(28K), a calcium-binding protein expressed by cerebellar Purkinje cells. RESULTS: Dose-related neurocerebellar toxicity associated with parasagittal bands of Purkinje cell degeneration and microglial activation in the cerebellar vermis were evident in rats treated with PEN 100-400 mg/kg i.p. as a single dose. Neuronal injury was not observed in other regions of the brain. Furthermore, neither clinical nor histopathological evidence of cerebellar toxicity was apparent in rats treated with similar total doses of PEN administered i.p. on a dailyx5-day dosing schedule. Similar histological findings, in an identical neuroanatomical distribution, were observed in rats treated with PEN orally; however, the magnitude of the neuronal toxicity was much less than in animals treated with equivalent doses of PEN administered i.p. Although acute lethality occurred in some rats treated with equimolar doses of DMPEN as a single i.p. treatment, surviving animals exhibited neither signs nor histopathological evidence of neurocerebellar toxicity. CONCLUSIONS: PEN produces selective dose- and schedule-dependent Purkinje cell degeneration in the cerebellar vermis of rats, whereas therapeutically relevant doses of PEN administered orally are better tolerated and produce less neurocerebellar toxicity. In addition, roughly equivalent, albeit intolerable, doses of the major active metabolite DMPEN, which was lethal to some animals, produced neither clinical manifestations of neurocerebellar toxicity nor Purkinje cell loss. These results support a rationale for investigating whether PEN administered orally, which may undergo significant first-pass metabolism to DMPEN and other less toxic intermediates, or treatment with DMPEN, itself, may result in less neurocerebellar toxicity and superior therapeutic indices than PEN administered parenterally.

Synthesis and antitumor activity of several new analogues of penclomedine and its metabolites.

Analogues of penclomedine (PEN, 3,5-dichloro-4,6-dimethoxy-2-(trichloromethyl)pyridine) and its metabolites have been synthesized and evaluated as potential antitumor agents. PEN and 4-DMPEN (3,5-dichloro-4-hydroxy-6-methoxy2-(trichloromethyl)pyridine (3a)), the major plasma metabolite in patients, were modified at 4- and 6-positions with different alkyl, aryl, and ester groups. All of the analogues and many of the intermediates were evaluated against the PEN-sensitive MX-1 human breast tumor xenograft in vivo, and several analogues of PEN and 4-DMPEN showed modest to curative activity.