Pharmacokinetics of high-dose etoposide after short-term infusion

Summary The pharmacokinetics of high-dose etoposide (total dose, 2100 mg/m² divided into three doses given as 30-min infusions on 3 consecutive days) were studied in ten patients receiving high-dose combination chemotherapy followed by autologous bone marrow transplantation. In addition to etoposide, all subjects received 2×60 mg/kg cyclophosphamide and either 6×1,000 mg/m² cytosine arabinoside (ara-C), 300 mg/m² carmustine (BCNU), or 1,200 mg/m² carboplatin. Plasma etoposide concentrations were determined by²⁵²Cf plasma desorption mass spectrometry. In all, 27 measurements of kinetics in 10 patients were analyzed. According to graphic analysis, the plasma concentration versus time data for all postinfusion plasma ctoposide values were fitted to a biexponential equation. The mean values for the calculated pharmacokinetic parameters were:t1/2, 256±38 min; mean residence time (MRT), 346±47 min; AUC, 4,972±629g min ml^–1 (normalized to a dose of 100 mg/m²); volume of distribution at steady state (Vd_ss), 6.6±1.2l/m²; and clearance (CL), 20.4±2.4 ml min^–1 m^–2. A comparison of these values with standard-dose etoposide pharmacokinetics revealed that the distribution and elimination processes were not influenced by the dose over the range tested (70–700 mg/m²). Also, the coadministration of carboplatin did not lead to significant pharmacokinetic alterations. Although plasma etoposide concentrations at the time of bone marrow reinfusion (generally at 30 h after the last etoposide infusion) ranged between 0.57 and 2.39 g/ml, all patients exhibited undelayed hematopoietic reconstitution.     

Disposition of total and unbound etoposide following high-dose therapy

Total and unbound etoposide pharmacokinetics were studied in 16 adult patients (median age, 34 years; range, 18–61 years) undergoing autologous bone marrow transplantation for advanced lymphoma after receiving high-dose etoposide (35–60 mg/kg) as a single intravenous infusion. Pretreatment values for mean serum albumin and total bilirubin were 3.0±0.4 g/dl and 0.5±0.4 mg/dl, respectively. Etoposide plasma concentrations and protein binding (% unbound) were determined by high-performance liquid chromatography (HPLC) and equilibrium dialysis, respectively. Pharmacokinetic parameters for unbound and total etoposide were calculated by nonlinear regression analysis using a two-compartment model. Te mean (±SD) parameters for total etoposide included: clearance (CL), 31.8±17.7 ml min^–1 m^–2; volume of distribution (V_ss), 11.5±5.9 l/m², and terminal half-life (t _1/2 ), 7.2±3.7 h. Mean unbound CL was 209.6±62.7 ml min^–1 m^–2 and %unbound was 16%±5%. The mean etoposide %unbound was inversely related to serum albumin (r ²=0.45,P=0.0043). The mean %unbound at the end of the etoposide infusion was higher than that at the lowest measured concentration (21% vs 13%, respectively;P=0.017), suggesting that concentration-dependent binding may occur after high etoposide doses. The median total CL was higher in patients with serum albumin concentrations of 3.0 g/dl than in those with levels of >3.0 g/dl (34.6 vs 23.5 ml min^–1 m^–2,P=0.05). Total CL was directly related to %unbound (r ²=0.61,P=0.0004). Unbound CL was unrelated to either serum albumin or %unbound. These results demonstrate that hypoalbuminemia is independently associated with an increased etoposide %unbound and rapid total CL after the administration of high-dose etoposide. Unbound CL in hypoalbuminemic patients is unchanged in the presence of normal total bilirubin values.This study was supported in part by Bristol-Myers. Oncology Division     

Unaltered pharmacokinetics after the administration of high-dose etoposide without prior dilution

Summary The pharmacokinetics of etoposide following a new method of administration was determined. Undiluted etoposide was given at a dose of 30 mg/kg as part an intensified conditioning regimen prior to bone marrow transplantation. A terminal half-life of 3.4±0.7 h and a volume of distribution of 15.4±9.61 were found (n=8); the AUC was 764±302 g h ml^–1. As compared with those obtained in other pharmacokinetic studies using etoposide diluted in normal saline, our data reflect full systemic bioavailability and unaltered pharmacokinetics. The application of undiluted etoposide makes the therapy easier and less time-consuming and avoids a high fluid volume and a high saline load.     

Drug monitoring of etoposide (VP16-213)

Summary Pharmacokinetic parameters established in 15 patients receiving parenterally administered etoposide (80–120 mg·m^-2) are reported. The etoposide assay by means of mass spectrometry after sample separation by thin-layer chromatography or high-pressure liquid chromatography used in this study has been described else-where [4]. Peak plasma levels (9.5–63.3 g·ml^-1), the area under the curve (AUC) (2707–10192 g·ml^-1·min^-1), the mean transit time MTT (2.7–10.6 h), etoposide half-lives t1/2 (0.10–0.52 h) and t1/2 (2.18–8.17 h), the volume of distribution at steady state (Vd_ss) (2.5–15.1·l/m^-2) and the systemic clearance (Cl_s) (10.1–35.1 ml min^-1·m^-2) with the resulting mean values and standard deviations were determined. Our findings are compared with those of other authors, especially with regard to the method of detection used. This comparison indicates similar individual deviations and shorter half-lives with increasing specificity of the employed assay. Four patients studied on 3 consecutive days and, in one instance, during two different cycles of chemotherapy showed no sign of accumulation or of accelerated excretion of etoposide. There was little intrapatient variability. The pharmacokinetic parameters were correlated to clinical and laboratory findings. Statistical analysis indicated that the AUC was increased by prior cisplatin therapy and in patients with elevated levels of alkaline phosphatase. The Cl_s was decreased by prior cisplatin therapy, in obese patients, and by elevated alkaline phosphatase. The t1/2 of etoposide was increased in older patients. Linear regression analysis yielded a grater Vd_ss in patients with lower serum albumin levels, but this correlation has not yet been found to be statistically significant.     

Pharmacokinetics and pharmacodynamics of prolonged oral etoposide in women with metastatic breast cancer

The pharmacokinetics and pharmacodynamics of prolonged oral etoposide chemotherapy were investigated in 15 women with metastatic breast cancer who received oral etoposide 100 mg as a single daily dose for up to 15 days. There was considerable interpatient variability in the day 1 pharmacokinetic parameters: area under the plasma concentration time curve (AUC) (0–24 h) 1.95±0.87 mg/ml per min (mean ± SD), apparent oral clearance 60.9±21.7 ml/min per 1.73 m², peak plasma concentration 5.6±2.5 g/ml, time to peak concentration 73±35 min and half-life 220±83 min. However, intrapatient variability in systemic exposure to etoposide was much less with repeated doses. The intrapatient coefficient of variation (CV) of AUC for day 8 relative to day 1 was 20% and for day 15 relative to day 1 was 15%, compared to the day 1 interpatient CV of 45%. Neutropenia was the principal toxicity. Day 1 pharmacokinetic parameters were related to the percentage decrease in absolute neutrophil count using the sigmoidal E_max equation. A good fit was found between day 1 AUC and neutrophil toxicity (R ²=0.77). All patients who had a day 1 AUC>2.0 mg/ml per min had WHO grade III or IV neutropenia. The predictive performance of the models for neutrophil toxicity was better for AUC (percentage mean predictive error 5%, percentage root mean square error 18.1%) than apparent oral clearance, peak plasma concentration, or daily dose (mg/m²). A limited sampling strategy was developed to predict AUC using a linear regression model incorporating a patient effect. Data sets were divided into training and test sets. The AUC could be estimated using a model utilizing plasma etoposide concentration at only two time points, 4 h and 6 h after oral dosing (R ²=98.9%). The equation AUC_pr=–0.376+0.631×C_4h+0.336×C_6h was validated on the test set with a relative mean predictive error of –0.88% and relative root mean square error of 6.4%. These results suggest monitoring of AUC to predict subsequent myelosuppression as a strategy for future trials with oral etoposide.Division of Haematology and Medical Oncology, Peter MacCallum Cancer Institute, Locked Bag 1, A'Beckett St, Melbourne 3000, Australia     

Pharmacokinetics of acridine-4-carboxamide in the rat,with extrapolation to humans

Summary The pharmacokinetics ofN-[2-(dimethylamino)ethyl]acridine-4-carboxamide (AC) were investigated in rats after i. v. administration of 18, 55 and 81 mol/kg [³H]-AC. The plasma concentration-time profiles of AC (as measured by high-performance liquid chromatography) typically exhibited biphasic elimination kinetics over the 8-h post-administration period. Over this dose range, AC's kinetics were first-order. The mean (±SD) model-independent pharmacokinetic parameters were; clearance (Cl), 5.3±1.1 1 h^–1 kg^–1; steady-state volume of distribution (Vss), 7.8±3.0 l/kg; mean residence time (MRT), 1.5±0.4 h; and terminal elimination half-life (t _1/2Z), 2.1±0.7 h (n=10). The radioactivity levels (expressed as AC equivalents) in plasma were 1.3 times the AC concentrations recorded at 2 min (the first time point) and remained relatively constant for 1–8 h after AC administration. By 6 h, plasma radioactivity concentrations were 20 times greater than AC levels. Taking into account the species differences in the unbound AC fraction in plasma (mouse, 16.3%; rat, 14.8%; human, 3.4%), allometric equations were developed from rat and mouse pharmacokinetic data that predicted a Cl value of 0.075 (range, 0.05–0.10; 95% confidence limits) 1 h^–1 kg^–1 and a V_ss value of 0.63 (range, 0.2–1.1) l/kg for total drug concentrations in humans.     

Cisplatin disposition in children and adolescents with cancer

Summary The disposition of cisplatin was evaluated in 28 children and adolescents with cancer, as part of a phase II clinical trial. Patients received either 30 mg/m² (11) or 90 mg/m² (17) of cisplatin as a 6-h IV infusion. Serum samples and divided urine collections were obtained over 48 h following completion of the cisplatin infusion, and were assayed in duplicate for total platinum by atomic absorption spectrophotometry. Serum samples obtained up to 4 h after three cisplatin infusions were assayed for parent (free) cisplatin following ultrafiltration. The mean (±SE) elimination half-life of free cisplatin in serum was 1.3 (±0.4) h. Serial serum concentrations of total platinum following 90 mg/m² dosages were adequately described by a biexponential equation. The mean (±SE) serum T_1/2 of total platinum was 0.42 (±0.10) h and the mean (±SE) T_1/2 was 44.43 (±8.24) h. The intercompartment distribution rate constants of a two-compartment kinetic model indicate extensive tissue accumulation of total platinum, with a rate of transport into tissue compartments (K₁₂) that is about six times the rate of transport out of tissues (K₂₁). The mean (±SE) renal clearance of total platinum from 0–3 h was 37.36 (±11.96) ml/min/m² and 35.8 (±13.6) ml/min/m² for the 30 mg/m² and 90 mg/m² groups, respectively. This value decreased to 3.25 (±0.94) and 2.16 (±0.4) ml/min/m² for the two groups by the 6–12 h interval, and remained between 1 and 3 ml/min/m² for the duration of the observation period. The ratio of total plantinum clearance to creatinine clearance decreased significantly(P<0.05) beginning 3 h post-infusion. The change in renal clearance of total platinum is apparently a function of two independent first-order processes for renal clearance of parent drug and cisplatin metabolites.     

Pharmacokinetics of mitomycin C in non-oat cell carcinoma of the lung

Summary The disposition kinetics of the cancer chemotherapeutic agent mitomycin C have been studied in six male patients receiving mitomycin C in combination with cisplatin and vinblastine for non-oat cell carcinoma of the lung. Following rapid IV administration of mitomycin C (10 mg/m²), serum concentration-time course data were biexponential, with biologic half-lives of 46.2 ± 12.1 min (mean ± SD). Pharmacokinetic analysis of data by the CSTRIP and NONLIN digital computer programs generated parameters which suggested extensive distribution (V_area=656.8±169.8 ml·kg^–1, mean ±SD) and, as reported for other alkylating agents, rapid elimination (total body clearance=10.3 ± 3.2 ml · kg^–1 · min^–1, mean ± SD). Interpatient variations in pharmacokinetic parameters were relatively small, suggesting that close monitoring of mitomycin C therapy might be unnecessary in patients with normal renal and hepatic function.     

Pharmacological attempts to improve the bioavailability of oral etoposide

Etoposide demonstrates incomplete and variable bioavailability after oral dosing, which may be due to its concentration and pH-dependent stability in artificial gastric and intestinal fluids. The use of agents that may influence etoposide stability and, thereby, bioavailability, was investigated in a number of clinical studies. Drugs that influence the rate of gastric emptying, while modulating the time of drug absorption, did not significantly alter the etoposide area under the concentration-time curve (AUC) or bioavailability. Specifically, metoclopramide had little effect on the etoposide absorption profile and did not significantly alter the AUC (AUC with etoposide alone, 68.4±20.3 g ml^–1 h, versus 74.3±25.9 g ml^–1 h with metoclopramide), suggesting that in most patients the drug is already emptied rapidly from the stomach. In contrast, propantheline produced a dramatic effect on etoposide absorption, delaying the time of maximal concentrationt _max from 1.1 to 3.5 h (P<0.01), but again without a significant improvement in drug AUC or bioavailability across the 24-h study period (AUC with etoposide alone 78.3±19.1 g ml^–1 h, versus 88.1±23.6 g ml^–1 h with propantheline). The effect of these drugs on the absorption of oral paracetamol, a drug included in the study as a marker of gastric emptying, was exactly the same as that found for etoposide, with no change in AUC being observed after metoclopramide or propantheline administration but a significant delay int _max being seen on co-administration with etoposide and propantheline. The co-administration of ethanol or bile salts (agents that significantly improved the stability of etoposide in artificial intestinal fluid) with oral etoposide similarly had no effect on improving the etoposide AUC or reducing the variability in AUC, suggesting that drug stability in vivo was not affected by these agents. In the third study the co-administration of cimetidine had no effect on the pharmacokinetics of oral or i.v. etoposide, despite the previous observation that etoposide stability was markedly improved at pH 3–5 as compared with pH 1 in artificial gastric fluid. This series of studies, designed to investigate factors that improved etoposide stability in laboratory studies, failed to demonstrate any potentially useful improvement in AUC or bioavailability in the clinical setting.     

Carboplatin and etoposide pharmacokinetics in patients with testicular teratoma

Summary The pharmacokinetics of carboplatin and etoposide were studied in four testicular teratoma patients receiving four courses each of combination chemotherapy consisting of etoposide (120 mg/m² daily×3), bleomycin (30 mg weekly) and carboplatin. The carboplatin dose was calculated so as to achieve a constant area under the plasma concentration vs time curve (AUC) of 4.5 mg carboplatin/ml x min by using the formula: dose=4.5×(GFR+25), where GFR is the absolute glomerular filtration rate measured by ⁵¹Cr-EDTA clearance. Carboplatin was given on either day 1 or day 2 of each course and pharmacokinetic studies were carried out in each patient on two courses. Etoposide pharmacokinetics were also studied on two separate courses in each patient on the day on which carboplatin was given and on a day when etoposide was given alone. The pharmacokinetics of carboplatin were the same on both the first and second courses, on which studies were carried out with overall mean ± SD values (n=8) of 4.8±0.6 mg/ml x min, 94±21 min, 129±21 min, 20.1±5.41, 155±33 ml/min and 102±24 ml/min for the AUC, beta-phase half-life (t_1/2), mean residence time (MRT), volume of distribution (Vd) and total body (TCLR) and renal clearances (RCLR), respectively. The renal clearance of carboplatin was not significantly different from the GFR (132±32 ml/min). Etoposide pharmacokinetics were also the same on the two courses studied, with overall mean values ±SD (n=8) of: AUC=5.1±0.9 mg/ml x min, t_1/2=40±9 min, t_1/2=257±21 min, MRT=292±25 min, Vd=13.3±1.31, TCLR=46±9 ml/min and RCLR=17.6±6.3 ml/min when the drug was given alone and AUC=5.3±0.6 mg/ml x min, t_1/2=34±6 min, t_1/2=242±25 min, MRT=292±25 min, Vd=12.5±1.81, TCLR=43±6 ml/min and RCLR=13.4±3.5 ml/min when it was given in combination with carboplatin. Thus, the equation used to determine the carboplatin accurately predicted the AUC observed and the pharmacokinetics of etoposide were not altered by concurrent carboplatin administration. The therapeutic efficacy and toxicity of the carboplatin-etoposidebleomycin combination will be compared to those of cisplatin, etoposide and bleomycin in a randomised trial.     

Pharmacokinetics of high-dose methotrexate in adult osteogenic sarcoma

The pharmacokinetics of 222 infusions of high-dose methotrexate (MTX) with leucovorin rescue were studied in 22 adults with osteosarcoma. To reduce the variability of plasma concentration, we individualized dose regimens using a Bayesian method to reach a concentration of 10^–3 M MTX at the end of an 8-h infusion. The mean concentration observed at the end of the infusion was 1016±143 mol/l. The mean dose delivered was 13.2±2 g/m². The clearance was 49.1±11.7 ml min^–1 m^–2. The decay of the plasma concentration of MTX after completion of the infusion followed a two-compartment model with at _1/2 of 2.66±0.82 h and at _1/2 of 15.69±8.63 h. The volume of distribution was 0.32±0.08 l/kg. As compared with previously published data, the interindividual and intraindividual variations in the concentration at the end of the infusion were reduced, with values of 14% and 5.9%–21%, respectively, being obtained. Severe toxicities were avoided, and there were only 3 hematologic and 8 digestive grade 3 side effects and no grade 4 complication. Thet _1/2 and the MTX plasma concentrations at 23 and 47 h were correlated with renal toxicity (P<0.001). However, no correlation was found between the pharmacokinetic parameters and other signs of toxicity. There was no significant difference in pharmacokinetics between the toxic and nontoxic groups. In the same manner, the parameters of the group of patients sensitive to MTX were not statistically significantly different from those of the group of nonsensitive patients.     

The clinical pharmacokinetics of the novel antifolate N10-propargyl-5,8-dideazafolic acid (CB 3717)

Summary The pharmacokinetics of the new antifolate CB 3717 were studied in 20 patients during its phase-I clinical evaluation. The drug was administered at doses of 100–550 mg/m² in 1-h and 12-h infusions, resulting in peak plasma concentrations of CB 3717 of 40–200 M. There was a linear relationship between the dose and both CB 3717 AUC and peak plasma levels. Following a 1-h infusion, drug levels in the plasma decayed biphasically (t_1/2=49±9 min, t_1/2=739±209 min). 27%±2% of the dose was excreted in urine in the 24-h period after treatment, suggesting that the major route of elimination was via the bile. Furthermore, the parent compound CB 3717 and its desglutamyl metabolite, CB 3751, were found in a faecal collection although the metabolite was not detected in plasma or urine samples. Plasma protein binding of CB 3717 was extensive (97.6%±0.1%). Significant quantities of CB 3717 penetrated into ascitic fluid but not into cerebrospinal fluid.Residual drug was detected in postmortem kidney tissue from a patient who died of progressive disease 8 days after treatment with 330 mg/m² CB 3717. Thus, dose-limiting renal toxicity (maximum tolerated dose 600 mg/m²) may be due to drug precipitation in the renal tubules. Elevation of liver enzymes, in particular transaminases, occurred frequently as a toxic manifestation of CB 3717 therapy. In 11 patients studied after their first treatment there was a positive correlation between the rise in serum alanine transaminase and peak drug levels (r=0.69, P=0.02)These pharmacokinetic studies have shown that, by analogy with experimental systems, cytotoxic plasma levels of CB 3717 are archieved in man. In addition, they have been valuable in interpreting toxicities observed during phase-I clinical studies.This work was supported by grants from the Medical Research Council and Cancer Research Campaign, U. K.     

Pharmacokinetics of cisplatin given at a daily low dose as a radiosensitiser

Summary A total of 25 patients with inoperable cervical cancer were treated by daily radiotherapy (2 Gy); sensitisation was obtained by administration of 5 mg cisplatin 30 min before each irradiation session. The total cumulative dose of cisplatin varied between 50 and 150 mg. A complete kinetic profile (0–24 h) of platinum (Pt) was established after the first dose and at the end of treatment for 22 patients. Pt was quantified by atomic absorption spectrophotometry using Zeeman-effect background correction for trace analysis. The total Pt AUC_{0–24 h} increased from 1.53±0.77 to 7±3.55 g·h·ml^–1 between the start and the end of treatment (P<0.001). Ultrafilterable Pt (Pt UF) rose from 0.079±0.038 to 0.138±0.095 g·h·ml^–1 (P<0.01). Elimination half-lives were unchanged for total Pt but rose for Pt UF; these kinetic modifications in Pt UF did not correlate with any significant change in individual serum creatinine levels. No clear correlation was found between the cumulative cisplatin dose and tumor levels measured in 13 patients, and the tumor cisplatin dose did not correlate with response to treatment. Patients with hematological toxicity were characterised by an increase in their residual Pt UF level during treatment. Overall, our findings strengthen the notion of Pt UF kinetic variability during repeated treatment.     

A limited sampling method for estimation of the etoposide area under the curve

A limited sampling method for estimation of the etoposide area under the curve (AUC) is presented. The method was developed and validated in 23 patients (42 pharmacokinetic studies) with small-cell lung cancer (SCLC), limited disease. The patients received 100 mg/m² etoposide as a 90-min intravenous infusion in combination with carboplatin, allowing for etoposide dose modification at a following course (25% increase or decrease) due to high or low nadir values for leukocytes or thrombocytes. Of the 42 pharmacokinetic studies, 27 were used in the model development and 15 were used in the model validation. Single regression analyses of the AUC versus the fitted concentrations for the model data set were performed at several time points. The analyses demonstrated high and essentially identical correlation coefficients in the interval between 2 and 21 h, with a maximal value of 0.96 being recorded at 4 h. Multiple regression analysis was then performed using fitted concentrations corresponding to 0.08–21 h. The best model for one sample was AUC =1.01x(dose level divided by 100 mg/m²)+799×C_{4 h}, that for two samples was AUC=1.43x(dose level divided by 100 mg/m²)+544×C_{4 h}+1756×C_{21 h}, and that for three samples was AUC=0.07x(dose level divided by 100 mg/m²)+110×C_{5 min}+474×C_{4 h}+1759×C_{21 h}. Not unexpectedly, the model validation revealed that the one-sample model was less precise than the two- or three-sample model [percentage of root mean squared error (RMSE%)=11.6%, 7.1%, and 5.4%, respectively]. All models proved to be unbiased in the validation [percentage of mean predictive error (MPE%) ±SE=4.2%±11.0%, 7.9%±6.1%, and 6.3%±5.3%, respectively]. The models were subsequently validated in 14 pharmacokinetic studies of patients with metastatic germ-cell tumours who were receiving combination chemotherapy with cisplain and bleomycin plus 100 mg/m² etoposide as a 90-min infusion. The RMSE% was 13.4%, 10.8%, and 9.0% and the MPE%±SE was –1.0%±11.9%, 1.7%±10.5%, and 2.7%±7.9% for the one-, two-, and three-sample models, respectively. The limited sampling methods presented herein may prove to be a most valuable tool for therapeutic drug monitoring in regimens in which etoposide is given in combination with carboplatin or with cisplatin and bleomycin.Supported by grants from the Lundbeck Foundation, the Research Foundation of the Oncology Department in Aarhus, and Asta and Peter Gøtz-Petersen's Foundation     

Evaluation of plasma 5-fluorouracil nucleoside levels in patients with metastatic breast cancer: relationships with toxicities

This paper describes the relationship between 5-fluorouracil (FUra)-derived toxicities and plasma levels of the FUra anabolites 5-fluorouridine (FUrd) and 5-fluoro-2-deoxyuridine (FdUrd) monitored in patients receiving continuous infusions of FUra (1000 mg/m² per 24 h) over 5 days preceded by the administration of cisplatin (100 mg/m²). A total of 63 courses of this treatment were given as second-line chemotherapy to 17 patients with metastatic breast cancer. The active FUra anabolites FUrd and FdUrd were monitored twice daily in the plasma by highperformance liquid chromatography. Data were analyzed using multiple analysis of variance (ANOVA). Only a low proportion of patients exhibited measurable plasmatic levels of FUrd (43%) and FdUrd (70%). The areas under the plasma concentration-time curves (AUC) determined over 120 h for FUrd (AUC_FUrd) and for FdUrd (AUC_FdUrd) were found to be statistically significantly different for chemotherapy cycles with and those without myelosuppression. Chemotherapy cycles without neutropenia were associated with low AUC_FUrd values (mean±SEM, 2.9±0.7 g ml^–1 h) and high AUC_FdUrd values (14.1±2.7 g ml^–1 h), respectively, whereas courses with myelosuppression (WHO grades 2–4) showed inverse profiles with high AUC_FUrd values (16.3±2.3 g ml^–1 h) and low AUC_FdUrd values (3.1±1.0 g ml^–1 h), respectively. A statistically significant difference in AUC_FdUrd values was also observed between cycles with and those without mucositis (P=0.0027), with AUC_FdUrd values being 22.6±5.6 and 7.8±1.9 g ml^–1 h, respectively. Whereas hematotoxicity could be correlated with both AUC_FUrd and AUC_FdUrd values, mucositis was associated with high AUC_FdUrd levels. Moreover, a negative correlation was found between the AUCs determined for FUrd and FdUrd (P=0.002), indicating that activation of FUra via FUrd or via FdUrd may involve competitive processes. Therefore, to follow the development of the major FUra-derived toxicities, measurement of FUrd and FdUrd plasma levels appeared very attractive.     

Oral bioavailability of docetaxel in combination with OC144-093 (ONT-093)

Objective Docetaxel given orally as monotherapy results in low bioavailability of <10%. Previous studies have indicated that the intestinal efflux pump P-glycoprotein (P-gp) prevents uptake from the gut resulting in low systemic exposure to docetaxel. The purpose of this study was to determine the degree of enhancement of the oral uptake of docetaxel on combination with orally administered OC144-093, a potent P-gp inhibitor. Furthermore, the safety of combined treatment was determined and whether known functional genetic polymorphisms of the MDR1 gene could be associated with variability in docetaxel pharmacokinetics was also investigated.Patients and methods A proof of concept study was carried out in 12 patients with advanced solid tumors. Patients were randomized to receive one course of 100 mg oral docetaxel combined with 500 mg OC144-093 followed 2 weeks later by a second i.v. course of docetaxel at a flat dose of 100 mg, without OC144-093, or vice versa. This was followed by standard i.v. docetaxel treatment if indicated.Results The apparent relative oral bioavailability of docetaxel was 26±8%. Orally administered docetaxel combined with oral OC144-093 resulted in a C_max of 415±255 ng ml^–1, an AUC_0– of 844±753 ng h ml^–1 and k_el of 0.810±0.296 h^–1. These values differed significantly from those following i.v. administration of docetaxel, with a C_max of 2124±1054 ng ml^–1, an AUC_0– of 2571±1598 ng h ml^–1 and a k_el of 1.318±0.785 h^–1 (P=0.003, P=0.006, P=0.016). The study medication was well tolerated and most of the adverse events possibly or probably related to OC144-093 and docetaxel were of CTC grade 1 and 2. One patient had a homozygous 3435T/T mutation, which is associated with low intestinal P-gp expression, and two other patients had a homozygous mutation on exon 21.Conclusion The relative apparent bioavailability of 26% was most likely caused by a significant effect of OC144-093 on the oral uptake of docetaxel. Large intrapatient and interpatient (pharmacokinetic) variation was found after oral as well as after i.v. administration of docetaxel. Higher plasma levels were observed after 100 mg i.v. docetaxel than after 100 mg oral docetaxel plus 500 mg oral OC144-093. The safety of the oral combination was good. More patients should be evaluated to determine the effect of P-gp single nucleotide polymorphisms on oral pharmacokinetic values of docetaxel.     

Pharmacokinetics of low-dose doxorubicin and metabolites in patients with AIDS-related Kaposi sarcoma

Purpose Systemic chemotherapy is the treatment of choice for AIDS-related advanced Kaposi sarcoma. One principal schedule combines adriamycin (doxorubicin), bleomycin, and vincristine (ABV). We analysed the plasma concentrations of low-dose doxorubicin (Dx) and its metabolites doxorubicinol, 7-deoxydoxorubicinone, doxorubicinone, doxorubicinolone, and 7-deoxydoxorubicinolone in AIDS-patients to define patient-group and dose-specific pharmacokinetic parameters.Materials and methods A previously described high-performance liquid chromatographic (HPLC) method and a population approach with non-linear mixed effects modelling (NONMEM) were used for analysis and subsequent modelling of the time–concentration data of low-dose Dx and metabolites in seven patients with AIDS-related advanced Kaposi sarcoma. Patients received Dx 20 mg m^–2, bleomycin 15 U m^–2 and vincristine 2 mg as a 30-min intravenous infusion each. Blood samples were collected up to 72 h after the start of Dx treatment. WinNonlin software version 4.1 was used for non-compartmental analysis and NONMEM software version V for compartmental analysis. Covariate analysis was performed for various clinical and laboratory parameters.Results Non-compartmental analysis yielded an area under the plasma concentration–time curve (AUC) for Dx of 566 g h L^–1, a maximum plasma concentration (c_max) of 599 g L^–1 and an elimination half-life (t_1/2) of 30.8 h. Compartmental analysis resulted in a two-compartment model with first-order elimination, which best fitted the concentration–time data. Model estimate for Dx clearance was 61.8 L h^–1, for intercompartmental clearance (Q) 112 L h^–1, for the volume of the central compartment (V₁) 23.3 L, and for the volume of the peripheral compartment (V₂) 1,130 L. Metabolite data could adequately be estimated by NONMEM using single-compartment models. Graphical plots of residuals versus time for all metabolites yielded no evidence of non-linear pharmacokinetic behaviour. Laboratory parameters of liver and renal function were all in the normal range and their inclusion in the pharmacokinetic model did not improve data fit. A final jack-knife analysis was performed.Conclusions Concentration–time data for low-dose Dx and metabolites in the ABV-regimen are best described by a two-compartment model with first-order elimination. The results confirm that the aglycones doxorubicinone, 7-deoxydoxorubicinone, and doxorubicinolone can be reliably detected in the studied patient group and implemented into a common metabolic model. Model estimates suggest that pharmacokinetic parameters are similar for low-dose Dx and higher-dosed Dx. As the role of the aglycones is still poorly understood, despite their potential clinical relevance, their analysis should be implemented in future pharmacokinetic and pharmacodynamic studies of Dx.     

Pharamacokinetic Modeling for Boronophenylalanine-fructose Mediated Neutron Capture Therapy: 10B Concentration Predictions and Dosimetric Consequences

A two-compartment open model has been developed for predicting ¹⁰B concentrations in blood following intravenous infusion of the L-p-boronophenylalanine-fructose complex in humans and derived from pharmacokinetic studies of 24 patients in Phase I clinical trials of boron neutron capture therapy. The ¹⁰B concentration profile in blood exhibits a characteristic rise during the infusion to a peak of 32g/g (for infusion of 350mg/kg over 90min) followed by a biexponential disposition profile with harmonic mean half-lives of 0.32±0.08 and 8.2±2.7h, most likely due to redistribution and primarily renal elimination, respectively. The mean model rate constants k ₁₂, k ₂₁, and k ₁₀ are (mean ± SD) 0.0227±0.0064min^–1, 0.0099±0.0027min^–1, 0.0052±0.0016min^–1, respectively, and the central compartment volume of distribution V ₁ is 0.235±0.042L/kg. In anticipation of the initiation of clinical trials using an intense neutron beam with concomitantly short irradiations, the ability of this model to predict, in advance, the average blood ¹⁰B concentration during brief irradiations was simulated in a retrospective analysis of the pharmacokinetic data from these patients. The prediction error for blood boron concentration and its effect on simulated dose delivered for each irradiation field are reported for three different prediction strategies. In this simulation, error in delivered dose (or, equivalently, neutron fluence) for a given single irradiation field resulting from error in predicted blood ¹⁰B concentration was limited to less than 10%. In practice, lower dose errors can be achieved by delivering each field in two fractions (on two separate days) and by adjusting the second fraction's dose to offset error in the first.     

Pharmacokinetics and toxicity of the antitumour agentN-[2-(dimethylamino)ethyl]acridine-4-carboxamide after i.v. administration in the mouse

Summary The pharmacokinetics, tissue distribution and toxicity of the antitumour agentN-[2-(dimethylamino)ethyl]acridine-4-carboxamide(AC) were studied after i.v. administration to mice. Over the dose range of 9–121 mol/kg (3–40 mg/kg), AC displayed linear kinetics with the following model-independent parameters: clearance (C), 21.0±1.9 l h^–1 kg^–1; steady-state volume of distribution (V_ss), 11.8±1.4 l/kg; and mean residence time (MRT), 0.56±0.02 h. The plasma concentration-time profiles for AC fitted a two-compartment model with the following parameters:C _c, 19.4±2.3 l h^–1 kg^–1; V_c, 7.08±1.06 l/kg;t _1/2 13.1±3.5 min; andt _1/2Z, 1.60±0.65 h. AC displayed moderately high binding in healthy mouse plasma, giving a free fraction of 15.9%–25.3% over the drug concentration range of 1–561 M. After the i.v. administration of 30 mol/kg [³H]-AC, high radioactivity concentrations were observed in all tissues (especially the brain and kidney), showing a hight _1/2c value (37–59 h). At 2 min (first blood collection), the AC concentration as measured by high-performance liquid chromatography (HPLC) comprised 61% of the plasma radioactivity concentration (expressed as AC equivalents/l). By 48 h, 73% of the dose had been eliminated, with 26% and 47% of the delivered drug being excreted by the urinary and faecal routes, respectively; <1% of the total dose was excreted as unchanged AC in the urine. At least five distinct radiochemical peaks were distinguishable by HPLC analysis of plasma extracts, with some similar peaks appearing in urine. The 121-mol/kg dose was well tolerated by mice, with sedation being the only obvious side effect and no significant alterations in blood biochemistry or haematological parameters being recorded. After receiving a dose of 152 mol/kg, all mice experienced clonic seizures for 2 min (with one death occuring) followed by a period of sedation that lasted for up to 2h. No leucopenia occurred, but some mild anaemia was noted. There was no significant change in blood biochemistry. A further 20% increase in the i.v. dose (to 182 mol/kg) resulted in mortality, with death occurring within 2 min of AC administration.Supported by the Auckland Medical Research Foundation and the Cancer Society of New Zealand     

Bioavailability and pharmacokinetics of the cardioprotecting flavonoid 7-monohydroxyethylrutoside in mice

Purpose The pharmacokinetics and bioavailability of monoHER, a promising protector against doxorubicin-induced cardiotoxicity, were determined after different routes of administration.Methods Mice were treated with 500 mg.kg^–1 monoHER intraperitoneally (i.p.), subcutaneously (s.c.) or intravenously (i.v.) or with 1000 mg.kg^–1 orally. Heart tissue and plasma were collected 24 h after administration. In addition liver and kidney tissues were collected after s.c. administration. The levels of monoHER were measured by HPLC with electrochemical detection.Results After i.v. administration the AUC_{0–120 min} values of monoHER in plasma and heart tissue were 20.5±5.3 mol.min.ml^–1 and 4.9±1.3 mol.min.g^–1 wet tissue, respectively. After i.p. administration, a mean peak plasma concentration of about 130 M monoHER was maintained from 5 to 15 min after administration. The AUC_{0–120 min} values of monoHER were 6.1±1.1 mol.min.ml^–1 and 1.6±0.4 mol.min.g^–1 wet tissue in plasma and heart tissue, respectively. After s.c. administration, monoHER levels in plasma reached a maximum (about 230 M) between 10 and 20 min after administration. The AUC_{0–120 min} values of monoHER in plasma, heart, liver and kidney tissues were 8.0±0.6 mol.min.ml^–1, 2.0±0.1, 22.4±2.0 and 20.5±5.7 mol.min.g^–1, respectively. The i.p. and s.c. bioavailabilities were about 30% and 40%, respectively. After oral administration, monoHER could not be detected in plasma, indicating that monoHER had a very poor oral bioavailability.Conclusions MonoHER was amply taken up by the drug elimination organs liver and kidney and less by the target organ heart. Under cardioprotective conditions (500 mg/kg, i.p.), the C_max was 131 M and the AUC was 6.3 M.min. These values will be considered endpoints for the clinical phase I study of monoHER.