A randomized study of epirubicin at four different dose levels in advanced breast cancer. Feasibility of myelotoxicity prediction through single blood-sample measurement

Summary Detailed pharmacokinetic analysis and subsequent evaluation of myelotoxicity were performed in 55 patients who had been randomized to 4 different doses of epirubicin (40, 60, 90 or 135 mg/m² given i.v. every 3 weeks). A significantly positive correlation was demonstrated between the AUC and the myelotoxicity of epirubicin. A similar correlation was observed when the metabolite epirubicinol was also considered. The decrease in leucocyte count as expressed by the logarithmic ratio between nadir WBC and initial WBC was linearly correlated with the AUC of either epirubicin alone (r=–0.55,P<0.001) or epirubicin and epirubicinol together (r=–0.63,P<0.001). As a relationship between the concentration of epirubicin in a single plasma sample taken at 6 h following i.v. administration and the AUC of the drug has been established, a log-linear relationship between the expected decrease in leucocytes and the concentration at 6 h after administration could be calculated. The proposed model is expressed as the equation: log WBC_nadir=log WBC_initial–0.0073×c ₆ (ng/ml) –0.14.This work was supported by the Lundbeck Foundation, the Michaelsen Foundation and Farmitalia Carlo Erba Ltd.     

Epirubicin metabolism and pharmacokinetics after conventional- and high-dose intravenous administration: a cross-over study

In a pharmacokinetics study, six patients were treated i.v. with epirubicin (EPI) at the two dose levels of 60 and 120 mg/m², whereas a further six patients were treated at 75 and 150 mg/m². Both groups were studied according to a balanced cross-over design; the aim of the study was to assess the pharmacokinetic linearity of epirubicin given at high doses. Both the absolute goodness of fit and the Akaike Information Criterion (AIC) point to a linear, tricompartmental open model as the choice framework for discussing EPI plasma disposition after 16/24 administrations, independent of the delivered dose. After 8 treatments, the minimal AIC value corresponded to a nonlinear tissue-binding model. However, even in these cases, second-order effects were present only during the early minutes following treatment. In a model-independent framework, mean EPI plasma clearance was identical at the two dose levels of 60 and 120 mg/m² (65.4±8.0 vs 65.3±13.4 l/h,P=0.92). Both the mean residence time (MRT) and the volume of distribution at steady-state (V_ss) were similar as well (MRT: 22.6±2.9 vs 24.2±3.7 h;P=0.46; V_ss: 21.3±1.5 vs 22.6±6.5 l/kg,P=0.46). No statistically significant difference could be found in mean statistical-moment-theory parameters determined after 75- and 150-mg/m² EPI doses (plasma clearance, PICI: 83.4±13.5 vs 68.5±12.8 l/h,P=0.12; MRT: 22.6±4.8 vs 21.9±3.9 h,P=0.60; V_ss: 26.7±10.5 vs 21.2±7.0 l/kg,P=0.17). Analysis of variance also failed to reveal any significant correlation between dose and plasma clearance. However, when data relative to single patients were examined, a trend toward nonlinear drug distribution as well as a consequent increase in peripheral bioavailability could be observed in 4/6 patients of the 75-mg/m² vs the 150-mg/m² group. No significant dose-dependent variation was observed in the ratio between the molecular-weight-corrected areas under the concentration-time curve for the metabolites and those for EPI [60 vs 120 mg/m²: epirubicinol (EPIol), 0.23±0.10 vs 0.22±0.06,P=0.20; epirubicin glucoronide (G1), 0.46±0.14 vs 0.62±0.40,P=0.26; epirubicinol glucuronide (G2), 0.21±0.05 vs 0.30±0.16,P=0.06; and 75 vs 150 mg/m²: EPIol, 0.33±0.22 vs 0.32±0.19,P=0.42; G1, 0.51±0.23 vs 0.46±0.17,P=0.53; G2, 0.18±0.10 vs 0.22±0.10,P=0.34]. In conclusion, all the metabolic pathways seemed well preserved when the dose was doubled, and no evident sign of saturation kinetics could be found.     

Prochlorperazine as a doxorubicin-efflux blocker: phase I clinical and pharmacokinetics studies

Summary Doxorubicin (DOX) efflux in drug-resistant cells is blocked by phenothiazines such as trifluoperazine (TFP) and prochlorperazine (PCZ) in vitro. The present phase I study was conducted in 13 patients with advanced, incurable, nonhematologic tumors to determine whether PCZ plasma levels high enough to block DOX efflux could be achieved in vivo. The treatment schedule consisted of prehydration and i. v. administration of 15, 30, 50, and 75 mg/m² PCZ followed by a standard dose of 60 mg/m² DOX. The hematologic toxicities attributable to DOX were as expected and independent of the PCZ dose used. Toxicities attributable to PCZ were sedation, dryness of the mouth, cramps, chills, and restlessness. The maximal tolerated dose (MTD) of PCZ in this schedule was 75 mg/m². Pharmacokinetic analysis indicated a large interpatient variation in peak plasma PCZ levels that ranged from 95 to 1100 ng/ml. The three plasma half-lives of PCZ were:t ₁/2 (±SE), 20.9±5.3 min;t1/2, 1.8±0.3 h; andt1/2, 21.9±5.3 h. The volume of distribution (V_d), total clearance (Cl_T), and area under the curve (AUC) for PCZ were 2254±886 l/m², 60.2±13.5 l m^–2h^–1, and 1624±686 ng ml^–1 h, respectively. DOX retention in tumor cells retrieved from patients during the course of therapy indicated the appearance of cells with enhanced DOX retention. The combination of DOX and high-dose i. v. PCZ appeared to be safe, well tolerated, and active in non-small-cell lung carcinoma.Supported in part by the Joan Levy Cancer Foundation and by NIH-NCI grants CA-44737 and CA-29360     

Pharmacokinetics of etoposide: correlation of pharmacokinetic parameters with clinical conditions

Summary The pharmacokinetic parameters of etoposide were established in 35 patients receiving the drug parenterally within the framework of different polychemotherapy protocols. A total of 62 data for 24-h kinetics were analysed. After sample extraction and high-performance liquid chromatography (HPLC) or thin-layer cromatographic (TLC) separation, etoposide was measured by means of [²⁵²Cf]-plasma desorption mass spectrometry (PDMS). This highly specific detection system proved to be very practicable and reproducible. The present study comprised two parts that were absolutely comparable in terms of clinical and pharmacokinetic parameters. In part II of the study, sensitivity was improved by modifying the analytical technique. After the exclusion of patients who had previously been given cisplatin or who exhibited renal impairment and of one patient who showed extremely high levels of alkaline phosphatase, -GT and SGPT, the mean values calculated for the pharmacokinetic parameters evaluated were: beta-elimination half-life (t _1/2), 4.9±1.2 h; mean residence time (MRT), 6.7±1.4 h; area under the concentration-time curve (AUC), 5.43±1.74 mg min ml^–1; volume of distribution at steady state (Vd_ss), 6.8±2.7 l/m²; and clearance (Cl), 18.8±5.3 ml min^–1 m^–2. The pharmacokinetic parameters were correlated with 12 different demographic or biochemical conditions. Impaired renal function, previous application of cisplatin and the age of patients were found to influence etoposide disposition to a statistically significant extent. We suggest that the dose of etoposide should be reduced in elderly patients and/or in individuals with impaired renal function, especially in those exhibiting general risk factors such as reduced liver function with regard to the polychemotherapy.     

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 4′-O-tetrahydropyranyladriamycin given on a weekly schedule in patients with advanced breast cancer

Improved quality of life has gained importance over shortly lasting remissions in yet incurable metastatic breast cancer. Fractionation of drug administration is one of the possible approaches to reduce the concentration-dependent toxicity of anthracyclines. We evaluated the pharmacokinetics of 4-O-tetrahydropyranyladriamycin (THP-ADM) under weekly administration in patients with advanced breast cancer (dose escalation, from 20 to 27 mg/m₂ THP-ADM). The concentration-time curves of THP-ADM in plasma were best described by an open three-compartment model [half-life of the first disposition phase (t_1/2), 3.15 min; terminal elimination half-life (t _1/2), 13.9 h] with a mean area under the curve (AUC) of 12.2 ng h ml^–1mg^–1m^–2, resulting in a mean plasma clearance of 86.91 h^–1m^–2. Metabolism included the formation of Adriamycin (ADM), Adriamycinol (ADM-OH), 13-dihydro-4-O-tetrahydropyranyladriamycin (THP-OH), 7-deoxyadriamycinone (7H-ADn), and 7-deoxy-13-dihydroadrimycinone (7H-ADn-OH), with maximal plasma concentrations ranging from 2.8 to 5.5 ng/ml. The mean total amount of cytotoxic anthracyclines excreted into urine, mainly as the parent drug, was 5% of the delivered dose. ADM and ADM-OH, but not the parent drug, were observed in urine at up to 4 weeks after the last therapeutic cycle. There was a significant correlation between the leukocyte nadir under therapy and the AUC of ADM-OH (r=0.800,P<0.05). Since no shift in the plasma kinetics was observed from the first to the sixth cycle, the favorable ratio of the AUCs of THP-ADM and ADM after fractionation of THP-ADM suggests lower toxic side effects attributable to ADM. This hypothesis was confirmed in a clinical study, where no severe cardiotoxicity and only mild alopecia were observed in 19 patients. Thus, pharmacokinetics studies might be helpful in both individualization of therapy with THP-ADM and optimization of the administration schedule.     

Population pharmacokinetics of docetaxel during phase I studies using nonlinear mixed-effect modeling and nonparametric maximum-likelihood estimation

Docetaxel, a novel anticancer agent, was given to 26 patients by short i.v. infusion (1–2 h) at various dose levels (70–115 mg/m², the maximum tolerated dose) during 2 phase I studies. Two population analyses, one using NONMEM (nonlinear mixed-effect modeling) and the other using NPML (nonparametric maximum-likelihood), were performed sequentially to determine the structural model; estimate the mean population parameters, including clearance (Cl) and interindividual variability; and find influences of demographic covariates on them. Nine covariates were included in the analyses: age, height, weight, body surface area, sex, performance status, presence of liver metastasis, dose level, and type of formulation. A three-compartment model gave the best fit to the data, and the final NONMEM regression model for Cl wasCl=BSA(1+2×AGE), expressing Cl (in liters per hour) directly as a function of body surface area. Only these two covariates were considered in the NPML analysis to confirm the results found by NONMEM. Using NONMEM [for a patient with mean AGE (52.3 years) and mean BSA (1.68 m²)] and NPML, docetaxel Cl was estimated to be 35.6 l/h (21.2 lh^–1 m^–2) and 37.2 l/h with interpatient coefficients of variation (CVs) of 17.4% and 24.8%, respectively. The intraindividual CV was estimated at 23.8% by NONMEM; the corresponding variability was fixed in NPML in an additive Gaussian variance error model with a 20% CV. Discrepancies were found in the mean volume at steady state (Vss; 83.2 l for NPML versus 124 l for NONMEM) and in terminal half-lives, notably the meant _1/2, which was shorter as determined by NPML (7.89 versus 12.2 h), although the interindividual CV was 89.1% and 62.7% for Vss andt _1/2, respectively. However, the NPML-estimated probability density function (pdf) oft _1/2, was bimodal (5 and 11.4 h), probably due to the imbalance of the data. Both analyses suggest a similar magnitude of mean Cl decrease with small BSA and advanced age.     

Pharmacogenetics of adjuvant breast cancer treatment with cyclophosphamide,epirubicin and 5-fluorouracil

Purpose

Most adjuvant breast cancer treatment regimens include the combination of an anthracycline (epirubicin or doxorubicin) and the alkylating agent cyclophosphamide. This study sought to investigate the influence of pharmacogenetics on the pharmacokinetics and metabolism of these agents.

Methods

Blood samples were taken from patients treated with cyclophosphamide (n = 51) and epirubicin (n = 35), with or without 5-fluorouracil (5-FU). The pharmacokinetics and metabolism of the three drugs were investigated, together with pharmacogenetic investigations for cyclophosphamide and epirubicin. Cyclophosphamide and its metabolites and also epirubicin and epirubicinol were measured in plasma. DNA was extracted from whole blood and genotyping performed using RT-PCR.

Results

Patients with at least one variant CYP2C19*17 allele had a longer CP half-life (p = 0.007), as did homozygous variants for the CYP2B6*6 allele. There was no significant effect of GSTP1, CYP2B6*2, CYP2B6*5 or CYP2C19*2 on any pharmacokinetic parameter of CP. An NQO2 exonic SNP was associated with a higher exposure to epirubicinol relative to epirubicin (p = 0.011). Other polymorphic variants of NQO1, carbonyl reductase, UGT enzymes and transporters had no influence on epirubicin or its metabolite.

Conclusion

Overall, pharmacogenetic factors had only a minor influence on cyclophosphamide or anthracycline-based adjuvant therapy of breast cancer.     

Effects of verapamil on the pharmacokinetics and metabolism of epirubicin

Summary Experimental data suggest that multidrug resistance in cancer may be overcome by using an increased dose of anticancer agent(s) in combination with a resistance-modifying agent (RMA). We studied the pharmacokinetics and metabolism of both epirubicin (EPI) and verapamil (VPL) to explore the possible pharmacokinetic interactions between these two drugs. Ten patients with advanced breast cancer were given EPI (40 mg/m² in a daily i.v. bolus for 3 consecutive days), and five of them also received VPL (4×120 mg/daily p.o. for 4 consecutive days). The data indicated a significant interaction between these two drugs that affected their metabolism. The areas under the concentration-time curves (AUC) obtained for epirubicin glucuronide, epirubicinol glucuronide, and both of the 7-deoxy-aglycones were higher in the EPI+VPL group as compared with the EPI group. The AUC, terminal half-life, mean residence time, volume of distribution at steady state, and plasma clearance of EPI alone as compared with EPI+VPL did not differ significantly. These results suggest either an induction of enzymes necessary for drug metabolism or an increase in the liver blood flow, resulting in an enhanced generation of metabolites with time or in an inhibition of excretion processes. Comparisons of the AUC values obtained for EPI and its metabolites after the first, second, and third injections of EPI revealed a cumulative effect for the metabolites that was more pronounced in the EPI+VPL group, being significant (P<0.05) for epirubicin glucuronide in both treatment groups and for epirubicinol glucuronide in the EPI+VPL group. Maximal concentrations of VPL and nor-VPL reached 705±473 and 308±122 ng/ml, respectively, with the steady-state concentrations being 265±42 ng/ml for VPL and 180±12 ng/ml for nor-VPL.This study was supported by the Erich und Gertrud Roggenbuck-Stiftung zur Förderung der Krebsforschung (Hamburg). The anthracycline metabolites were kindly provided by Dr. A. Suarato (Farmitalia, Milano, Italy); nor verapamil was provided by Dr. Traugott (Knoll, Ludwigshafen, Germany)     

Clinical pharmacokinetics of high-dose DTIC

Summary The pharmacokinetics of 5-(3,3-dimethyl-1-triazeno)imidazole-4-carboxamide (DTIC, dacarbazine) given at a dose of 850–1,980 mg/m² as a 10- to 30-min infusion was studied in cancer patients, and the plasma concentration-time curves were adjusted to a two-compartment model, with a meant _1/2 value of 0.17 h (range, 0.1–0.26 h) and a meant _1/2 value of 2 h (range, 1.5–2.7 h) being found. The mean volume of the central compartment (V_c) and the apparent volume of distribution (V_B) were 0.42 l kg^–1 (range, 0.24–0.54 l kg^–1) and 1.49 l kg^–1 (range, 0.88–1.74 l kg^–1), respectively. The mean total body clearance of DTIC was 0.58 l kg^–1 h^–1 (range, 0.26–0.82 l kg^–1 h^–1), and the mean renal clearance was 0.28 l kg^–1 h^–1 (range, 0.17–0.49 l kg^–1 h^–1). Unchanged DTIC recovered from urine within 24 h varied from 11% to 63% of the delivered dose, with an inverse correlation being found between the DTIC dose and the amount excreted. The metabolite aminoimidazole carboxamide (AICA) was detectable in plasma from the start of DTIC infusion, and its concentration-time curve showed a monophasic decay, exhibiting a meant _1/2 value of 3.25 h (range, 1.77–5.82 h). Mean AICA renal clearance was 0.15 l kg^–1 h^–1 (range, 0.05–0.32 l kg^–1 h^–1). The amount of AICA excreted in urine increased with increasing DTIC dose and varied from 1.2% to 13.6% of the delivered DTIC dose. Both DTIC distribution and disposition and AICA production and renal excretion seemed to be limited after high DTIC doses as compared with the pharmacokinetics of low-dose DTIC. Nonlinear pharmacokinetics for highdose DTIC could not be clearly excluded.This work was supported in part by CAICYT grant 1182     

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.     

Pharmacokinetics of epirubicin in cancer patients

The plasma levels of epirubicin and its metabolite, epirubicinol, were measured by HPLC following intravenous administration of epirubicin to cancer patients at doses of 40, 60, 80, and 100 mg/m2. The blood concentration/time curve declined as a tri-phasic function. The mean t1/2 alpha, beta, and gamma were 4.67 min, 1.15 h, and 36.5 h, respectively, which were characterized by a short distribution phase (alpha) and a prolonged elimination phase (gamma). The distribution volume of the central compartment (V1 = 0.351 l/kg) was small, while that of the tissue compartment (V2 = 0.254, V3 = 45.8 l/kg) was large, which could be explained by the binding of the drug to cellular components. The concentration of epirubicinol, although having a wide variation among individuals, was less than that of the unchanged drug and showed a gradual decline. The area under the curve (AUC) of epirubicin increased in proportion to the increase of dosage. These types of pharmacokinetic behavior of epirubicin appeared to be similar to those of doxorubicin.     

Intraperitoneal administration of the antitumour agentN-[2-(dimethylamino)ethyl]acridine-4-carboxamide in the mouse: bioavailability,pharmacokinetics and toxicity after a single dose

Summary The pharmacokinetics, tissue distribution and toxicity of the antitumour agentN-[2-(dimethylamino)-ethyl]acridine-4-carboxamide (AC) were studied after i.p. administration of [³H]-AC (410 mol/kg) to mice. The latter is the optimal single dose for the cure of advanced Lewis lung tumours. AC was rapidly absorbed into the systemic circulation after i.p. administration, with the maximal concentration (C _max) occurring at the first time point (5 min). There was no reduction in bioavailability as compared with previous i.v. studies, but the shape of the plasma concentration-time profile was considerably different, reflecting a 3-fold lowerC _max value (20.9±3.6 mol/l) and a longert _1/2 value (2.7±0.3 h) as compared with that observed after i.v. administration (1.6±0.6 h). Model independent pharmacokinetic parameters after i.p. administration were: clearance (C), 17.5 l h^–1 kg^–1; steady-state volume of distribution (V_ss), 14.1 l/kg; and mean residence time (MRT), 1.46 h. High but variable tissue uptake of AC was observed, with tissue/plasma AUC ratios being 5.7 for heart, 8.4 for brain, 18.9 for kidney and 21.0 for liver but with similar eliminationt _1/2 values ranging from 1.3 to 2.7 h. All radioactivity profiles in plasma and tissues were greater than the respective parent AC profiles and showed prolonged eliminationt _1/2 values ranging from 21 h in liver to 93 h in brain. However, tissue/plasma radioactivity AUC ratios were near unity, ranging from 0.7 to 1.57, with the exception of the gallbladder (15.6), which contained greater amounts of radioactivity. By 48 h, approximately 70% of the total dose had been eliminated, with the faecal to urinary ratio being approximately 2:1. This i.p. dose was well tolerated by mice, with sedation being the only obvious side effect. No major change was observed in blood biochemistry or haematological parameters. Comparisons ofC _max,t _max and AUC values determined for AC in brain after its i.p. and i.v. administration suggest that the reduction in acute toxicity after i.p. administration is not due to reduced exposure of the brain to AC as measured by AUC but may be associated with the lowerC _max value or the slower rate of entry of AC into the brain after i.p. administration.This study was supported by the Cancer Society of New Zealand. The senior author (S.M.H.E.) is the recipient of a Health Research Council of New Zealand Junior Research Award     

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     

Pharmacokinetics of Amonafide in dogs

Summary Amonafide, one of a series of imide derivatives of 1,8-naphthalic acid synthesized by Brana et al. [2] has shown significant antitumor activity against a variety of experimental tumors, including L1210 leukemia and P388 leukemia. Along with the clinical trial at our institute, we have studied the disposition of Amonafide in dogs by HPLC and fluorometry. Six dogs received Amonafide i.v. at 5 mg/kg (100 mg/m²) over 15 min; three were sacrificed at 6 h, and three at 24 h. The initial plasma t_1/2, of Amonofide was 2.4±0.4 min, the intermediate t_1/2, 26.8±3.7 min, and the terminal t_1/2, 21.7±4.0 h. the peak plasma concentration achieved was 6.3±1.7 g/ml. The average apparent volume of distribution was 12.84±0.541/kg, and the total clearance was 0.56±0.161/kg/h. In 24 h, 9.5%±0.2% of the administered dose was excreted in the urine as the parent drug, and 7.4%±1.4% in the bile in 6 h. Amonafide penetrated the CSF readily and achieved the highest concentration 20–25 min after administration, which was 30% of the concurrent plasma level. Amonafide underwent extensive metabolism to at least three major metabolites and two or more minor metabolites. The and plasma t_1/2 of the major metabolite, an N-oxide derivative, were 24.8 min and 28.6 h, respectively. The 24-h cumulative urinary excretion was 1.4% of the injected dose, and the cumulative biliary excretion was 16.7% in 6 h. At autopsy 6 h after dosing, the liver contained the highest percentage (0.23% of administered dose) of unchanged Amonafide, followed by the stomach (0.11%), lung (0.04%), kidney (0.04%), and pancreas (0.03%). The rest of the major organs retained less than 0.02% of the Amonafide dose. One day after dosing, no detectable amount of Amonafide was found in any of these tissues, indicating that Amonafide appears to be extensively metabolized and not significantly retained in the dog.     

Involvement of breast epithelial-stromal interactions in the regulation of protein tyrosine phosphatase-γ (PTPγ) mRNA expression by estrogenically active agents

Background. Protein tyrosine phosphatase (PTP) has been implicated as a tumor suppressor gene in kidney and lung cancers. Our previous results indicate that estradiol-17 (E₂)-induced suppression of PTP may play a role in mammary tumorigenesis. Zeranol (Z), a nonsteroidal growth promoter with estrogenic activity that is used by the US meat industry, induces estrogenic responses in primary cultured breast cells and breast cancer cell lines. Methods. PTP mRNA expression in human breast tissues and cells isolated from surgical specimens of mammoplasty and breast cancer patients were detected and quantified by RT-PCR. Immunohistochemical staining was used to localize PTP in human breast tissues. Breast epithelial and stromal cells were isolated and co-cultured to determine the involvement of cell–cell interaction in the regulation of PTP mRNA expression by E₂ and Z. Results. PTP mRNA expression was lower in cancerous than in normal breast tissues. Both E₂ and Z suppressed PTP mRNA levels in cultured normal breast tissues by 80%, but had a lesser effect in cultured epithelial cells isolated from normal breast tissues. In the co-culture system, both E₂ and Z suppressed PTP mRNA to a greater degree in epithelial cells than in stromal cells. In whole breast tissues, PTP was immunolocalized to the epithelium. Treatment with E₂ or Z diminished PTP staining indicating reductions in PTP at the protein level. Conclusions. The results indicate that both E₂ and Z regulate PTP expression in human breast and that epithelial–stromal cells interaction is important in the regulation of PTP expression by estrogenically active agents.     

The effects of cimetidine upon the plasma pharmacokinetics of doxorubicin in rabbits

Summary Cimetidine is an H₂ antagonist which inhibits cytochrome P-450 and reduces hepatic blood flow. To determine whether cimetidine interferes with the plasma pharmacokinetics of doxorubicin, we gave six female New Zealand rabbits doxorubicin 3 mg/kg, followed a month later by cimetidine 120 mg/kg every 12 h over 72 h and doxorubicin 3 mg/kg. Serial plasma specimens were obtained over 72 h and assayed for doxorubicin and its metabolites by high-performance liquid chromatography and fluorescence detection.Doxorubicin plasma pharmacokinetics were prolonged after cimetidine pretreatment [AUC 0.76±0.22 vs. 2.85±1.22 M×h, no pretreatment vs pretreatment (p=0.005), half-life=11.7±6.55 vs 28.0±8.16 h (P=0.0002), and clearance=0.129±0.036 vs 0.036±0.0111/min^-1 kg^-1 (P=0.0007)]. No significant differences were found between the AUCs for doxorubicinol, 7-deoxy doxorubicinol aglycone, or two unidentified nonpolar metabolites in nonpretreatment and pretreatment studies. Cimetidine increases and prolongs the plasma exposure to doxorubicin in rabbits. Doxorubicin metabolism does not appear to be affected by cimetidine.Grant Support Veterans Administration, NIH Grant RR-05424 and Clinical Research Center Grant RR-00095 American Cancer Society Institutional Grants #IN25V and IN24V, and JFCF #649     

Dosing of thioTEPA for myeloablative therapy

High-dose thioTEPA is used frequently in myeloablative regimens for marrow transplantation, but the need for dose adjustments in obese patients has not been explored. We determined the pharmacokinetics of thioTEPA and its metabolite TEPA during first-dose infusion of thioTEPA 150–250 mg/m² given daily for 3 days in combination with busulfan and cyclophosphamide, and evaluated the results for correlations with toxicity and dosing strategies. The study included 15 adults undergoing marrow transplantation for hematologic malignancies. Plasma samples were obtained at various times over a 24-h period, and concentrations of thio TEPA and TEPA were measured by gas chromatography. At 22–24 h after initiation of a 4-h infusion, the mean ±SE plasma concentration of thioTEPA was 124±63 ng/ml, while that of TEPA was 235±69 ng/ml. For CFU-GM and BFU-E growth in vitro, the IC₅₀s of thioTEPA were 83 ng/ml and 16 ng/ml, respectively, and the IC₅₀s of TEPA were 141 ng/ml and 47 ng/ml, respectively. Using a twocompartment model, the mean thioTEPA Vc was 47.4±4.7 l/m², t_1/2 19±5 min,t _1/2 3.7±0.5 h, and plasma clearance 302±21 ml/min per m². The mean AUCs were 6.9–16.2 mg h/l for thioTEPA and 8.9–21.2 mg h/l for TEPA, while the mean peak concentrations were 0.95–2.08 g/ml for thioTEPA and 0.88–1.90 g/ml for TEPA. There was a significant association of grades 2–4 maximum regimen-related toxicity (RRT) with TEPA peak >1.75 g/ml and with combined thioTEPA and TEPA AUC >30 mgh/l (5/6 vs 0/9,P=0.01 for both comparisons), suggesting that drug exposure was an important determinant of toxicity and, potentially, efficacy. ThioTEPA Vc correlated best with adjusted body weight (r=0.74,P=0.0015). In an evaluation of 74 adults receiving thioTEPA 750 mg/m² in combination with busulfan and cyclophosphamide, the maximum RRT for patients at ideal weight was significantly greater than that for obese patients dosed on ideal weight (mean RRT grade 1.7 vs 1.0,P=0.004) but did not differ from the maximum RRT for obese adults dosed on actual or adjusted weights. We recommend that for obese patients thioTEPA be dosed on adjusted body weight. Measurements at time-points after 24 h are needed to determine when thioTEPA and TEPA concentrations are below myelosuppressive levels and safe for marrow infusion.Supported in part by a grant from the American Cyanamid Corporation     

Clinical pharmacokinetics of mitoxantrone after intraperitoneal administration

Summary The pharmacokinetics of intraperitoneally (i.p.) injected mitoxantrone was determined in plasma and peritoneal dialysate taken from five patients presenting with cancer confined to the peritoneal cavity over a sampling period of 1 week. The drug was given through a Tenckhoff catheter as a 15-min infusion and the peritoneal dialysate was removed after a dwell time of 4 h; the doses delivered varied between 20 and 50 mg/m². Dose-limiting local toxicity was moderate. The HPLC technique used for mitoxantrone determinations proved to be sensitive within the range of 0.3–4,000 ng/ml. Median values obtained for the pharmacokinetic parameters of mitoxantrone in peritoneal dialysate were:t _1/2 (distribution), 56.4 min (range, 16.8–235.8 min);t _1/2 (elimination), 128 h (range, 28.3–171.0 h); Vd_SS (volume of distribution at steady state), 24.8 l (range, 17.0–232.5 l); _ss (volume of distribution at steady state corrected for the body surface area in square meters), 14.4 l/m² (range, 10.6–129.2 l/m²); and clearance, 0.25 l/h (range, 0.16–0.59 l/h). For plasma the median values were:t _1/2 (absorption), 58.8 min (range, 45.6–87.0 min);t _1/2 (distribution), 2.5 h (range, 1.4–6.3 h);t _1/2 (elimination), 44.1 h (range, 9.1–91 h); Vd_SS, 2,152 l (range, 352–19,733 l); _ss, 1,345 l/m² (range, 220–11,606 l/m²); and clearance, 117 l/h (range, 51–1,609 l/h). After 168 h the median plasma concentration was 1 ng/ml. The median peak concentration in peritoneal dialysate was 490 ng/ml. Considering the moderate toxicity observed and the concentrations achieved in the peritoneal dialysate, removal of the dialysate after certain dwell times seems reasonable to be a reasonable approach for the optimization of i.p. treatment with mitoxantrone.     

Pharmacokinetic study of fludarabine phosphate (NSC 312887)

Summary Characterization of the pharmacokinetics of 2-FLAA has been completed in seven patients receiving 18 or 25 mg/m² daily x5 of 2-FLAMP over 30 min. Assuming 2-FLAMP was instantaneously converted to 2-FLAA, the plasma levels of 2-FLAA declined in a biexponential fashion. Computer fitting of the plasma concentrationtime curves yielded an average distribution half-life (t1/2) of 0.60 h and a terminal half-life (t1/2) of 9.3 h. The estimated plasma clearance was 9.07±3.77 l/h per m² and the steady state volume of distribution, 96.2±26.0 l/m². There was a significant inverse correlation between the area under the curve (AUC) and absolute granulocyte count (r=-0.94, P<0.02). A relationship between creatinine clearance and total body clearance was noted, but was not statistically significant (r=0.828; P<0.1). Aproximately 24%±3% of 2-FLAA was excreted renally over the 5-day course of drug administration.Abbreviations used 2-FLAA-9--D arabinofuranosyl-2-fluoroadenine - 2-FLAMP the 5'-monophosphate of 2-FLAA, also known as fludarabine phosphate - AUC area under the curve - AGC absolute granulocyte count - TPC total plasma clearance - Vd_ss volume of distribution at steady state - Vd volume of distribution - Creat Cl creatinine clearance - SGOT serum glutamic-oxaloacetic transaminase - WBC peripheral white blood cell count This study was supported by contract NCI N01-CM-27542, NIH grant RR-01346 and by the VA Research Service.