In Vitro Profiling and Mass Balance of the Anti-Cancer Agent Laromustine [14C]-VNP40101M by Rat, Dog, Monkey and Human Liver Microsomes

Development and Validation of LC-MS-MS Assay for the Determination of the Emerging Alkylating Agent Laromustine and Its Active Metabolite in Human Plasma

The objective of this study was to validate a method for the determination of laromustine (VNP40101M) and short-lived its active metabolite (VNP4090CE) that has a half-life in human blood of <90 s in human plasma by liquid chromatography (LC) with tandem mass spectrometric (MS/MS) detection. We overcome the stability dilemma by acidified the human plasma with citric acid. Laromustine "breaks" down on the source of mass spectrometry to give m/z 249 which is the same m/z for VNP4090CE. Because VNP4090CE and laromustine elute at approximate retention time of 1.93 and 2.94 min, respectively, we were able to quantify both of them in one method. VNP40101M, VNP4090CE and the internal standards were extracted from human plasma by liquid-liquid extraction into ethyl ether. The ethyl ether layer was evaporated, reconstituted and analyzed using LC with MS/MS detection. Validation parameters such as selectivity, limit of quantitation, linearity, precision, accuracy, recovery, autosampler viability, freeze-thaw cycles and compounds stability are evaluated for this method. Results were calculated using peak area ratios, and calibration curves were generated using a weighted (1/x2) linear least-squares regression. Calibration curves for VNP40101M and VNP4090CE in human plasma ranged from 1.00 to 1,000 ng/mL. In this study, both intra- and inter-assay results demonstrated a relative standard deviation for calibration standards (inter-assay) and quality control samples (intra- and inter-assay) to be ≤15.0%. In this method, there is ~1.79% isotopic interference of VNP40101M to VNP40101M-IS, and ~3.76% isotopic interference of VNP4090CE to VNP4090CE-IS. It was concluded that there was no significant carryover.

Population pharmacokinetic (PK) analysis of laromustine, an emerging alkylating agent, in cancer patients

1. Alkylating agents are capable of introducing an alkyl group into nucleophilic sites on DNA or RNA through covalent bond. Laromustine is an active member of a relatively new class of sulfonylhydrazine prodrugs under development as antineoplastic alkylating agents, and displays significant single-agent activity. 2. This is the first report of the population pharmacokinetic analysis of laromustine, 106 patients, 66 with hematologic malignancies and 40 with solid tumors, participated in five clinical trials worldwide. Of these, 104 patients were included in the final NONMEM analysis. 3. The population estimates for total clearance (CL) and volume of distribution of the central compartment (V₁) were 96.3 L/h and 45.9 L, associated with high inter-patient variability of 52.9% and 79.8% and inter-occasion variability of 26.7% and 49.3%, respectively. The population estimates for Q and V₂ were 73.2 L/h and 29.9 L, and inter-patient variability in V₂ was 63.1%, respectively. 4. The estimate of V_ss (75.8 L) exceeds total body water, indicating that laromustine is distributed to tissues. The half-life is short, less than 1 h, reflecting rapid clearance. Population PK analysis showed laromustine pharmacokinetics to be independent of dose and organ function with no effect on subsequent dosing cycles.

Biotransformation and Rearrangement of Laromustine

This review highlights the recent research into the biotransformations and rearrangement of the sulfonylhydrazine-alkylating agent laromustine. Incubation of [(14)C]laromustine with rat, dog, monkey, and human liver microsomes produced eight radioactive components (C-1 to C-8). There was little difference in the metabolite profile among the species examined, partly because NADPH was not required for the formation of most components, which instead involved decomposition and/or hydrolysis. The exception was C-7, a hydroxylated metabolite, largely formed by CYP2B6 and CYP3A4/5. Liquid chromatography-multistage mass spectrometry (LC-MS(n)) studies determined that collision-induced dissociation, and not biotransformation or enzyme catalysis, produced the unique mass spectral rearrangement. Accurate mass measurements performed with a Fourier-transform ion cyclotron resonance mass spectrometer (FTICR-MS) significantly aided determination of the elemental compositions of the fragments and in the case of laromustine revealed the possibility of rearrangement. Further, collision-induced dissociation produced the loss of nitrogen (N2) and methylsulfonyl and methyl isocyanate moieties. The rearrangement, metabolite/decomposition products, and conjugation reactions were analyzed utilizing hydrogen-deuterium exchange, exact mass, (13)C-labeled laromustine, nuclear magnetic resonance spectroscopy (NMR), and LC-MS(n) experiments to assist with the assignments of these fragments and possible mechanistic rearrangement. Such techniques produced valuable insights into these functions: 1) Cytochrome P450 is involved in C-7 formation but plays little or no role in the conversion of [(14)C]laromustine to C-1 through C-6 and C-8; 2) the relative abundance of individual degradation/metabolite products was not species-dependent; and 3) laromustine produces several reactive intermediates that may produce the toxicities seen in the clinical trials.

Metabolic disposition of the anti-cancer agent [(14)C]laromustine in male rats

1. Laromustine (VNP40101M, also known as Cloretazine) is a novel sulfonylhydrazine alkylating (anticancer) agent. This article describes the use of quantitative whole-body autoradiography (QWBA) and mass balance to study the tissue distribution, the excretion mass balance and pharmacokinetics after intravenous administration of [(14)C]VNP40101M to rats. A single 10 mg/kg IV bolus dose of [(14)C]VNP40101M was given to rats. 2. The recovery of radioactivity from the Group 1 animals over a 7-day period was an average of 92.1% of the administered dose, which was accounted for in the excreta and carcass. Most of the radioactivity was eliminated within 48 h via urine (48%), with less excreted in feces (5%) and expired air accounted for (11%). The plasma half-life of [(14)C]laromustine was approximately 62 min and the peak plasma concentration (Cmax) averaged 8.3 μg/mL. 3. The QWBA study indicated that the drug-derived radioactivity was widely distributed to tissues through 7 days post-dose after a single 10 mg/kg IV bolus dose of [(14)C]VNP40101M to male pigmented Long-Evans rats. The maximum concentrations were observed at 0.5 or 1 h post-dose for majority tissues (28 of 42). The highest concentrations of radioactivity were found in the small intestine contents at 0.5 h (112.137 µg equiv/g), urinary bladder contents at 3 h (89.636 µg equiv/g) and probably reflect excretion of drug and metabolites. The highest concentrations in specific organs were found in the renal cortex at 1 h (28.582 µg equiv/g), small intestine at 3 h (16.946 µg equiv/g), Harderian gland at 3 h (12.332 µg equiv/g) and pancreas at 3 h (12.635 µg equiv/g). Concentrations in the cerebrum (1.978 µg equiv/g), cerebellum (2.109 µg equiv/g), medulla (1.797 µg equiv/g) and spinal cord (1.510 µg equiv/g) were maximal at 0.5 h post-dose and persisted for 7 days. 4. The predicted total body and target organ exposures for humans given a single 100 µCi IV dose of [(14)C]VNP40101M were well within the medical guidelines for maximum radioactivity exposures in human subjects.