Pharmacokinetics and excretion of (14)C-omacetaxine in patients with advanced solid tumors.

Background Omacetaxine mepesuccinate is indicated in adults with chronic myeloid leukemia resistant and/or intolerant to ≥ 2 tyrosine kinase inhibitor treatments. This phase I study assessed the disposition, elimination, and safety of (14)C-omacetaxine in patients with solid tumors. Methods The study comprised a 7-days pharmacokinetic assessment followed by a treatment period of ≤ six 28-days cycles. A single subcutaneous dose of 1.25 mg/m(2) (14)C-omacetaxine was administered to six patients. Blood, urine, and feces were collected through 168 h or until radioactivity excreted within 24 h was <1 % of the dose. Total radioactivity (TRA) was measured in all matrices and concentrations of omacetaxine, 4'-desmethylhomoharringtonine (4'-DMHHT), and cephalotaxine were measured in plasma and urine. For each treatment cycle, patients received 1.25 mg/m(2) omacetaxine twice daily for 7 days. Results Mean TRA recovered was approximately 81 % of the dose, with approximately half of the radioactivity recovered in feces and half in urine. Approximately 20 % of the dose was excreted unchanged in urine; cephalotaxine (0.4 % of dose) and 4' DMHHT (9 %) were also present. Plasma concentrations of TRA were higher than the sum of omacetaxine and known metabolites, suggesting the presence of other (14)C-omacetaxine-derived compounds. Fatigue and anemia were common, consistent with the known toxicity profile of omacetaxine. Conclusion Renal and hepatic processes contribute to the elimination of (14)C-omacetaxine-derived radioactivity in cancer patients. In addition to omacetaxine and its known metabolites, other (14)C-omacetaxine-derived materials appear to be present in plasma and urine. Omacetaxine was adequately tolerated, with no new safety signals.

Metabolite profiling of 14C-omacetaxine mepesuccinate in plasma and excreta of cancer patients.

Omacetaxine mepesuccinate (hereafter referred to as omacetaxine) is a protein translation inhibitor approved by the US Food and Drug Administration for adult patients with chronic myeloid leukemia with resistance and/or intolerance to two or more tyrosine kinase inhibitors. The objective was to investigate the metabolite profile of omacetaxine in plasma, urine and faeces samples collected up to 72 h after a single 1.25-mg/m2 subcutaneous dose of 14C-omacetaxine in cancer patients. High-performance liquid chromatography mass spectrometry (MS) (high resolution) in combination with off-line radioactivity detection was used for metabolite identification. In total, six metabolites of omacetaxine were detected. The reactions represented were mepesuccinate ester hydrolysis, methyl ester hydrolysis, pyrocatechol conversion from the 1,3-dioxole ring. Unchanged omacetaxine was the most prominent omacetaxine-related compound in plasma. In urine, unchanged omacetaxine was also dominant, together with 4'-DMHHT. In feces very little unchanged omacetaxine was found and the pyrocatechol metabolite of omacetaxine, M534 and 4'-desmethyl homoharringtonine (4'-DMHHT) was the most abundant metabolites. Omacetaxine was extensively metabolized, with subsequent renal and hepatic elimination of the metabolites. The low levels of the metabolites found in plasma indicate that the metabolites are unlikely to contribute materially to the efficacy and/or toxicity of omacetaxine.

Validation of high-performance liquid chromatography-tandem mass spectrometry assays quantifying omacetaxine mepesuccinate and its 4'­des-methyl and cephalotaxine metabolites in human plasma and urine.

Omacetaxine mepesuccinate (hereafter called omacetaxine) is a modified cephalotaxine and is registered (Synribo(®)) for the treatment of adult patients with chronic myeloid leukemia (CML) with resistance and/or intolerance to two or more tyrosine kinase inhibitors (TKIs). To evaluate the pharmacokinetics of omacetaxine, sensitive high-performance liquid chromatography-tandem mass spectrometry (LC-MS/MS) assays for the quantification of omacetaxine and its inactive 4'-des-methyl (4'-DMHHT) and cephalotaxine metabolites in human plasma and urine were developed and validated. Since omacetaxine is mainly metabolised by esterases, the plasma samples were immediately stabilised after collection with an esterase inhibitor and stored at a nominal temperature of -80°C. Urine samples were stored at -80°C immediately after collection. Protein precipitation was applied as the sample pretreatment method for the plasma samples, and urine samples were processed using solid-phase extraction (SPE). For both assays, the dried and reconstituted extracts were injected on a XBridge BEH Phenyl column for analysis of all analytes. Gradient elution was applied with 0.1% formic acid in water and methanol as mobile phases. Analytes were ionised using a turbospray ionisation source in positive mode and detected with a triple quadrupole mass spectrometer. The validated plasma assay quantifies all analytes in the concentration range of 0.1-100ng/mL and the urine assay in the range of 0.1-50ng/mL. At all concentrations, the accuracies were within ±15% of the nominal concentrations and precisions were ≤15%. The developed methods have successfully been applied in a human mass balance study of omacetaxine.

Pharmacokinetic study of omacetaxine mepesuccinate administered subcutaneously to patients with advanced solid and hematologic tumors.

PURPOSE: Omacetaxine mepesuccinate is a first-in-class cephalotaxine demonstrating clinical activity in chronic myeloid leukemia. A subcutaneous (SC) formulation demonstrated efficacy and safety in phase 1/2 trials in patients previously treated with ≥1 tyrosine kinase inhibitor. This study assessed pharmacokinetics and safety of SC omacetaxine in patients with advanced cancers. METHODS: Omacetaxine 1.25 mg/m(2) SC was administered BID, days 1-14 every 28 days for 2 cycles, until disease progression or unacceptable toxicity. Blood and urine were collected to measure omacetaxine concentrations and inactive metabolites. Adverse events, including QT interval prolongation, were recorded. Tumor response was assessed at cycle 2 completion. RESULTS: Pharmacokinetic parameters were estimated from cycle 1, day 1 data in 21 patients with solid tumors or hematologic malignancies and cycle 1, day 11 data in 10 patients. Omacetaxine was rapidly absorbed, with mean peak plasma concentrations observed within 1 h, and widely distributed, as evidenced by an apparent volume of distribution of 126.8 L/m(2). Plasma concentration versus time data demonstrated biexponential decay; mean steady-state terminal half-life was 7 h. Concentrations of inactive metabolites 4'-DMHHT and cephalotaxine were approximately 10 % of omacetaxine and undetectable in most patients, respectively. Urinary excretion of unchanged omacetaxine accounted for <15 % of the dose. Grade 3/4 drug-related adverse events included thrombocytopenia (48 %) and neutropenia (33 %). Two grade 2 increases in QTc interval (>470 ms) were observed and were not correlated with omacetaxine plasma concentration. No objective responses were observed. CONCLUSIONS: Omacetaxine is well absorbed after SC administration. Therapeutic plasma concentrations were achieved with 1.25 mg/m(2) BID, supporting clinical development of this dose and schedule.

Quantitation of homoharringtonine in plasma by high-performance liquid chromatography with amperometric detection.

A high-performance liquid chromatographic procedure was developed for the quantitation of homoharringtonine in plasma. Harringtonine was used as an internal standard, and 1 ml of sample was required. The single-step extraction with dichloromethane resulted in almost 100% recovery for homoharringtonine and harringtonine. Analysis was performed on a reversed-phase CN column with amperometric detection. Chromatography was completed in 12 min. At an oxidation potential of +1.0 V, the detection limit was 1 ng/ml at a signal-to-noise ratio of 2. The mean analytical recovery for homoharringtonine was 99.5%. The within-run precision and between-run precision were both less than 11%. The method is equally applicable for plasma or serum, and it has been demonstrated to be applicable for study of the pharmacokinetics of homoharringtonine in patients suffering from acute non-lymphocytic leukaemia.

Clinical pharmacology of homoharringtonine.

Clinical pharmacokinetics of homoharringtonine (HHT) were studied in eight patients who received uniformly labeled HHT at 3-4 mg/m2 (150 mu Ci) by continuous 6-hour infusion. The drug and metabolites were quantified by radiochemical and high-performance liquid chromatographic techniques. Computerized nonlinear least-square regression and curve stripping were used to characterize HHT and total [3H]HHT equivalent pharmacokinetics. Unchanged HHT in the plasma declined biphasically, with an alpha-half-life of 0.5 +/- 0.1 hours and a beta-half-life of 9.3 +/- 1.4 hours. The total clearance of HHT was 177.4 +/- 27.7 ml X hour-1 X kg-1, and the apparent volume of distribution, estimated from the area under the drug concentration versus time curve, was 2.4 +/- 0.4 L X kg-1. Correspondingly, the total [3H]HHT equivalent disappeared from the plasma in a triphasic manner. Compared with the pharmacokinetic parameters of unchanged HHT, the terminal half-life of total 3H was 67.5 +/- 7.5 hours, 7.4 times longer; the total clearance was 30.9 +/- 3.1 ml X hour-1 X kg-1, 5.5 times slower; but the volume of distribution by area was 2.7 +/- 0.1 L X kg-1, nearly the same. The 72-hour cumulative urinary excretion of total tritium was 28.2% of the administered dose and only 38.3% of this resided in unchanged HHT. Thus, urinary excretion was not a major route of elimination of HHT. Moreover, HHT underwent extensive metabolism; one major and two minor unidentified products were detected in both plasma and urine.

Quantification of homoharringtonine and harringtonine in serum by chemical ionization mass spectrometry.

Homoharringtonine and harringtonine are esters of cephalotaxine and are naturally occurring alkaloids in certain coniferous trees in China. These compounds have been shown to have activity against certain types of leukemia in cell cultures, experimental animals, and initial clinical trials in China, and will undergo Phase I trials in several institutions. A gas chromatographic mass spectrometric technique was developed for the quantification of both drugs in serum. One drug serves as internal standard for the other. The drugs are extracted from serum with dichloromethane and are quantified by monitoring the protonated molecular ions of the trimethylsilyl derivatives obtained by chemical ionization (methane). Masses monitored are: m/z = 690 for homoharringtonine and m/z = 676 for harringtonine. Detection limit: 10 ng ml-1 (20 nmol); reproducibility: 1.6-15.0% in the 0-200 ng ml-1 range. Serum levels of harringtonine reached 145 ng mg-1 upon intraperitoneal injection of 3 mg kg-1 in BDF-3 mice.

Quantitation of harringtonine and homoharringtonine in serum by high-performance liquid chromatography.

Harringtonine and homoharringtonine are naturally occurring alkaloids with demonstrated antineoplastic activity against certain types of leukemias in cell cultures, experimental animals, and initial clinical trials. Sample preparation consists of addition of the internal standard (one compound used as the internal standard for the other), solvent extraction with methylene chloride, washing with ammonium formate, and evaporation to dryness. The residue is dissolved in the mobile phase (40% methanol-60% 0.1 M ammonium formate) and an aliquot is chromatographed on a microC 18 reversed-phase column (flow-rate 1.5 ml/min). Peaks are detected with a spectrophotofluorimeter by monitoring the emission at 320 nm with excitation wavelength of 280 nm. Limit of detection is 10 ng/ml (20 nM) for both compounds; reproducible quantitation can be made to 30 ng/ml (60 nM).