Gemcitabine, epirubicin and paclitaxel: pharmacokinetic and pharmacodynamic interactions in advanced breast cancer.

BACKGROUND: The objectives of this study were to investigate the disposition of gemcitabine, epirubicin, paclitaxel, 2',2'-difluorodeoxyuridine and epirubicinol, and characterize the pharmacokinetic and pharmacodynamic profile of treatment in patients with breast cancer. PATIENTS AND METHODS: The drug dispostion in 15 patients who received gemcitabine 1000 mg/m2, epirubicin 90 mg/m2 and paclitaxel 175 mg/m2 (GEP) on day 1 of a 21-day cycle, was compared with that of patients treated with epirubicin 90 mg/m2 and paclitaxel 175 mg/m2 (EP, n = 6) and epirubicin 90 mg/m2 alone (n = 6). Drug and metabolite levels in plasma and urine were assessed by high-performance liquid chromatography and parameters of drug exposure were related to hematological toxicity by a sigmoid-maximum effect (Emax) model. RESULTS: Paclitaxel administration significantly increased the epirubicinol area under the concentration-time curve, from 357+/-146 (epirubicin) to 603+/-107 (EP) and 640+/-81 h x ng/ml (GEP), and reduced the renal clearance of epirubicin and epirubicinol by 38 and 52.2% and 34.5 and 53% in GEP- and EP-treated patients, respectively, compared with epirubicin alone. Gemcitabine had no apparent effect on paclitaxel and epirubicin pharmacokinetics, and renal clearance of epirubicin and epirubicinol. The only pharmacokinetic/pharmacodynamic relationship observed was between neutropenia and the time spent above the threshold plasma level of 0.1 micromol/l (tC0.1) of paclitaxel, with the time required to obtain a 50% decrease in neutrophil count (Et50) of GEP being 7.8 h, similar to that of EP. CONCLUSIONS: Paclitaxel and/or its vehicle, Cremophor EL, interferes with the disposition and renal excretion of epirubicin and epirubicinol; gemcitabine has no affect on epirubicin and paclitaxel plasma pharmacokinetics and renal excretion of epirubicin, while neutropenia is not enhanced by gemcitabine.     

Pharmacokinetics of KRN 8602 in cancer patients]

The pharmacokinetic properties of KRN 8602, an anthracycline compound, was studied by HPLC following intravenous administration of KRN 8602 to cancer patients. The results were as follows. (1) The plasma concentration-time curve declined as a triphasic function (alpha, beta, gamma) (t1/2 (alpha) = 0.02910, +/- 0.0054 hr, t1/2 (beta) = 0.704 +/- 0.319 hr, t1/2 (gamma) 8.37 +/- 1.37 hr). The blood cell concentration was higher than that in plasma. (2) The distribution volumes of the tissue compartment were larger than those of the central compartment. This result suggested that KRN 8602 would be easily transferred into the tissues. (3) The area under the curve (AUC) of KRN 8602 increased in proportion to the increase of dosage. (4) The metabolites of KRN 8602 were detected in plasma, blood cell and urine. (5) Urinary excretion of KRN 8602 and its metabolites were extremely low.     

Multiple-dose pharmacokinetics of epirubicin at four different dose levels: studies in patients with metastatic breast cancer

Summary Pharmacokinetic analysis of epirubicin and its metabolites epirubicinol and 7-deoxy-13-dihydro-epirubicinol aglycone during the first and the fourth courses of treatment was performed in 78 patients with metastatic breast cancer. The patients were treated every 3 weeks with epirubicin given as 10-min i.v. infusions at four different dose levels: 40, 60, 90 and 135 mg/m². In most cases (76 of 78 cases), plasma concentration-time curves fitted to a three-compartmental pharmacokinetic model. The terminal half-life of epirubicin was independent of dose and duration of treatment. Large interindividual differences were demonstrated (meant _1/2, 21.6±7.9 h; range, 10.6–69 h;n=110). In two subjects, extremely long half-lives and high serum bilirubin concentrations indicated impaired liver function. No correlation was found between the half-life and levels of liver alanine aminotransferase (ALAT) or serum creatinine. The metabolite epirubicinol appeared quickly after epirubicin administration and its half-lives were shorter than that of the parent compound (meant _1/2, 18.1±4.8 h; range, 8.2–38.4 h;n=105).Formation of the aglycone metabolite was delayed and the half-life of this metabolite was shorter than that of epirubicin (meant _1/2, 13±4.6 h; range, 2.7–29 h;n=104). The AUC of epirubicin and the total AUC (drug and metabolites) were linearly proportional to the dose, with the former value constituting two-thirds of the latter. A correlation was found between AUC and the plasma concentration of epirubicin at two time points (2 and 24 h after administration). The proposed model was AUC=9.44×c ₂+62.5×c ₂₄+157.7 (r=0.953).This work was supported by the Lundbeck Foundation, the Michaelsen Foundation and Farmitalia Carlo Erba Ltd.     

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.     

Clinical pharmacokinetics of intravenously injected tritiated vinzolidine

Vinzolidine (VZL), a novel, semi-synthetic vinca alkaloid showing evidence of oncolytic activity in phase I/II clinical trials, was studied in six patients for its pharmacokinetic and metabolic behavior. Following i.v. administration of [3H]-VZL at doses of 5, 6.7, and 9 mg/m2, blood and urine samples were collected and analyzed by sample oxidation and HPLC. Following a single i.v. dose, decay of total tritium in plasma was tetraphasic, with a rapid initial t1/2 alpha of 0.044 +/- 0.013 h, followed by a t1/2 beta of 0.54 +/- 0.22 h and a t1/2 gamma of 9.48 +/- 4.89 h; the terminal t1/2 gamma was 219 +/- 57 h. The mean plasma clearance of total tritium was 0.054 +/- 0.044 l.kg/h, and the mean volume of distribution was 14.3 +/- 5.4 l/kg; mean urinary excretion was 13.6% +/- 4.3% of the delivered radioactivity. Qualitative analysis of plasma and urine revealed the predominance of unchanged VZL plus two unidentified metabolites with different elution times. In comparison with oral VZL, as previously reported, i.v. injected VZL showed comparable values with respect to the volume of the central compartment (VC), plasma clearance (Clp), and terminal t1/2 for total tritium. Qualitatively, the metabolites observed in plasma and urine were comparable in number and quantity with values obtained in analyses after oral administration.     

Pharmacokinetics of tiazofurin in the plasma and cerebrospinal fluid of rhesus monkeys

The pharmacokinetic disposition of tiazofurin in plasma and cerebrospinal fluid was examined in rhesus monkeys. Tiazofurin was readily detectable in both plasma and cerebrospinal fluid within 20 min of commencement and for 24 h after a short i.v. infusion of the drug. The mean clearance of tiazofurin from plasma was 70 +/- 23 (SD) ml/min/sq m after a dose of 100 mg/kg and 106 +/- 38 ml/min/sq m after a dose of 500 mg/kg with no evidence of dose dependency. The data for plasma elimination of tiazofurin were fit to a triexponential equation for comparison with data from other species. The t 1/2 alpha was 0.23 h, t 1/2 beta was 1.9 to 2.0 h, and t 1/2 gamma was 6.8 to 7.1 h. The ratio of area under the cerebrospinal fluid drug concentration-time curve to the area under the plasma drug concentration-time curve was 0.28, which suggests significant penetration of the blood-brain barrier. These results demonstrate the propensity of tiazofurin to enter the cerebrospinal fluid and, probably, the brain, and suggest a potential role for this agent in the treatment of central nervous system cancer.     

Plasma pharmacokinetics and pharmacodynamics of a new prodrug N-l-leucyldoxorubicin and its metabolites in a phase I clinical trial.

PURPOSE: N-l-leucyldoxorubicin (Leu-Dox) was developed as a prodrug of doxorubicin (Dox) to circumvent the cardiotoxicity associated with repeated administration of Dox. Our purpose was to assess the pharmacokinetics of Leu-Dox, Dox, doxorubicinol (Dol) and four other metabolites for pharmacokinetically guided dose-escalation and to verify the prodrug character of Leu-Dox. PATIENTS AND METHODS: Blood and urine of 14 patients were sampled during the phase I clinical trial and analyzed by high-performance liquid chromatography. Dose levels of Leu-Dox ranged from 18 mg/m2 to 225 mg/m2, the maximum-tolerated dose (MTD). Hematologic parameters were monitored regularly in each patient. RESULTS: Leu-Dox was rapidly distributed (half-life at alpha phase [t1/2 alpha] = 2.5 +/- 0.6 minutes) followed by a biphasic elimination (half-life at beta phase [t1/2 beta] = 17.4 +/- 7.3 minutes; half-life at gamma phase [t1/2 gamma] = 1.5 +/- 0.5 hours), as measured over the first 12 hours after administration. In three patients, in whom Leu-Dox was found in the plasma for up to 48 hours after injection, a final elimination half-life (t1/2,elim) of 16 hours was observed. The t1/2,elim of Leu-Dox was short (0.6 to 16.5 hours) compared with the t1/2,elim of Dox (38 +/- 11 hours). The mean residence time and apparent volume of distribution were 23 +/- 5 minutes and 19 +/- 6 L/m2, respectively. Only 1.5% to 5% of the dose was excreted in the urine over 48 hours, with Dox as major constituent. Dox was rapidly formed, reaching its maximum concentration within 10 minutes after the end of Leu-Dox infusion. Areas under the plasma concentration versus time curve (AUC infinity, mean +/- SD, n = 16) of Leu-Dox, Dox, and Dol were 115 +/- 27 mumol.min/L, 41 +/- 12 mumol.min/L, and 33 +/- 14 mumol.min/L after a dose of 60 mg/m2 Leu-Dox (= 86 mumol/m2). After the same molar dose of Dox (50 mg/m2 = 86 mumol/m2), the AUC infinity of Dox was 179 mumol.min/L, indicating that Leu-Dox was converted into Dox for 23% in the plasma compartment. The AUCs infinity of Leu-Dox, Dox, and Dol increased linearly with the dose. Negligible AUCs were observed for the other four metabolites. The AUCs infinity of Leu-Dox and Dox at the MTD (517 and 145 mumol.min/L, respectively) were lower than those in mice at the LD10 (1,930 and 798 mumol.min/L, respectively), which means that the MTD could not be predicted from the preclinical pharmacokinetics in mice. Hematologic toxicity, especially the WBC count, appeared to correlate much better with the AUC of Dox (r = .91) than with the AUC of Leu-Dox (r = .74), thus confirming the prodrug character of Leu-Dox. CONCLUSIONS: Dox is rapidly formed from Leu-Dox, and seems causative in the observed myelotoxicity. The MTD could not be predicted from the AUC at the LD10 in mice.     

The relative toxicity of intravenous and intraperitoneal doses of epirubicin

Summary The toxicity of single doses of the anthracycline epirubicin was compared in the rat after either the intravenous (i.v.: 2–6 mg/kg) or intraperitoneal (i.p.; 4–8 mg/kg) administration of the drug. These doses produced comparable acute toxicity that was characterised by a dose-dependent, transient reduction in body weight (<15%) in the first 2 weeks after drug administration. Sequential measurements of cardiac output in animals that received i.v. doses of epirubicin showed that the time-related changes in cardiac function were biphasic. There was an initial decline in cardiac output in the first 12 weeks, which was followed by a phase of persistent depression in cardiac output between 12 weeks and 20 weeks. The time-related changes in cardiac function after i.p. doses of the drug were more variable, although the trend of changes, as after i.v. administration, appeared to be dose-dependent. Recovery of cardiac function occurred at 20 weeks after an i.p. dose of 4 mg/kg; however, after 6 mg/kg, cardiac function was significantly depressed after 16 weeks. For both routes of administration, the likelihood of late cardiac complications was dependent on the level of the reduction in cardiac output at 12 weeks. A study of the impairment of cardiac output and the incidence of cardiac-related mortality demonstrated that epirubicin was more cardiotoxic after i.v. administration. Equivalent cardiotoxic doses of epirubicin after i.v. and i.p. administration were highly linearly correlated (r=0.998), although there appeared to be a threshold dose of 3.33 mg/kg after i.p. administration of the drug. Thus, the relative cardiotoxicity between the two routes of administration was found to be dependent on the drug dose and, hence, the level of effect. The difference in the effect was less for high drug doses. The LD₅₀ for deaths due to cardiotoxicity at 20 weeks was 4.42±0.42 mg/kg after i.v. administration, which was significantly lower than the value of 6.28±0.41 mg/kg obtained after i.p. administration of the drug (P<0.01). There was no qualitative difference in the histological lesions induced in the myocardium after the i.v. vs i.p. administration of epirubicin.     

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.     

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.     

A population analysis of the pharmacokinetics of Cremophor EL using nonlinear mixed-effect modelling

PURPOSE: The purpose of this study was to develop a population pharmacokinetic model for Cremophor EL used as a formulation vehicle for paclitaxel. METHODS: Plasma concentration-time data from 70 patients (85 courses) treated with paclitaxel dissolved in Cremophor EL were used. The nonlinear mixed-effect modelling (NONMEM) program was used for the population pharmacokinetic analysis. The influence of patient characteristics on the pharmacokinetics of Cremophor EL was determined. The stability of the final model was evaluated using bootstrapping. RESULTS: The data were optimally fitted to a three-compartment model with Michaelis-Menten elimination from the central compartment. The following pharmacokinetic parameters were estimated: volume of the central compartment (V1=2.59 l), volumes of two peripheral compartments (V2=1.81 l, V3=1.61 l), intercompartmental clearance between central and peripheral compartments (Q12=1.44 l/h, Q13=0.155 l/h), maximal elimination rate (Vmax=0.193 ml/h), and concentration at half Vmax (Km=0.122 ml/l). Interindividual variability of the pharmacokinetic parameters was quantified for V1 (25%), V2 (36%) and Vmax (31%). Residual variability consisted of a combined additional (0.095 ml/l) and proportional error (7%). Gender, body surface area and performance status according to the World Health Organization were significantly correlated with V1, V2 and Vmax, respectively ( P<0.0001). The median parameter estimates of 1000 bootstrap samples were in accordance with those obtained with the original data set, indicating the validity of the population model. CONCLUSIONS: The population model was able to adequately describe the pharmacokinetic parameters and influence of covariates on the pharmacokinetics of Cremophor EL. This model can be used when studying the relationship between the pharmacokinetics and toxicity of Cremophor EL, and the drug's influence on the pharmacokinetics of paclitaxel.     

Pharmacokinetics of intraperitoneally administered dipyridamole in cancer patients

The pharmacokinetics of i.p. administered dipyridamole was studied in six patients to explore the feasibility of using this drug as a modulator of antimetabolite activity in extravascular spaces. Infusions of dipyridamole (50 mg/m2 in 2 liters of normal saline) into the peritoneal cavity resulted in peak drug concentrations 5 to 20 times higher in that cavity than in the plasma. The peritoneal decay data for dipyridamole fitted very well to a single compartment open pharmacokinetic model with one exponential term, while the plasma data are adequately described by a single compartment model with two exponentials (a short absorption phase). The mean peritoneal half-life for total extractable dipyridamole was 3.3 +/- 1.9 (SD) h, and the mean peritoneal clearance was 0.4 +/- 0.3 liters/h/m2. The mean plasma half-life of total dipyridamole in our patients was 2.2 +/- 1.2 h, and the mean clearance value was 5.7 +/- 4.7 liters/h/m2. The area under the concentration versus time curve was calculated to be 626 +/- 312 microM-h for the peritoneal cavity and 45 +/- 20 microM-h for the plasma. Using membrane ultrafiltration, we have measured the concentration of free (non-protein bound) dipyridamole in each patient. While the peritoneal clearance values of free and total drug are comparable, the plasma clearance of free dipyridamole was 47 +/- 39 liters/h/m2. This increased plasma clearance resulted in a plasma area under the concentration versus time curve of 8.3 +/- 5.1 microM-h, which suggests minimal systemic exposure. Our data show that instillation of dipyridamole into the peritoneal cavity resulted in much higher local drug exposure than systemic exposure, confirming the feasibility of using this drug to augment antimetabolite activity within the peritoneal cavity. Since dipyridamole is highly protein bound in the plasma but less so in the peritoneal cavity, these data imply that peritoneal exposure to active (free) dipyridamole is far greater than systemic exposure in our patients.     

高剂量表阿霉素在肿瘤患者中的药物动力学和药效学研究

目的：研究高剂量表阿霉素（ＥＰＩ）在肿瘤化疗患者体内的药物动力学过程,并初步探讨药效学特点。方法：１１例肿瘤患者接受了包含１００ｍｇ／ｍ＾２高剂量ＥＰＩ的联合化疗,高效液相色谱法（ＨＰＬＣ）测定血药浓度,ＰＬＮＯＮＬＩＮ程序进行药动力学房室模型数据拟合和参数计算;血液学毒性指标作为药效学参数,进行药动力学和药效学相关性及剂量调整因素的研究。结果：高剂量ＥＰＩ的消除具有典型的三室特征,患者对ＥＰＩ的     

Influence of trastuzumab on epirubicin pharmacokinetics in metastatic breast cancer patients.

BACKGROUND: Anthracycline cardiotoxicity is increased by the contemporaneous administration of trastuzumab. The mechanism by which it occurs is as yet unknown. The aim of this study was to evaluate whether trastuzumab modifies the pharmacokinetics of epirubicin and its metabolites. PATIENTS AND METHODS: Women with HER2-positive metastatic breast cancer were treated with epirubicin 75 mg/m(2) i.v. bolus followed by docetaxel 75 mg/m(2) in a 1-h infusion, every 3 weeks for six cycles, and trastuzumab (once at 4 mg/m(2), then 2 mg/m(2) weekly thereafter) in a 30-min infusion. Epirubicin pharmacokinetic data of seven patients were evaluated at the first cycle of therapy (baseline, with trastuzumab administered 24 h after epirubicin), and at the sixth cycle (i.e. 15 weeks after baseline, with trastuzumab administered immediately before epirubicin). RESULTS: No pharmacokinetic change in the parent compound epirubicin was detected. The area under the plasma concentration-time curve (AUC(0-24 h)) was 1230 +/- 318 [mean +/- standard deviation (SD)] at the first cycle and 1287 +/- 385 h. micro g/l at the sixth. The mean (+/-SD) maximum plasma concentration (C(max)) and the terminal elimination half-life at the first cycle (1303 +/- 490 micro g/l and 12.5 +/- 3.1 h, respectively) were similar to those obtained at the sixth cycle (1229 +/- 580 micro g/l and 11.5 +/- 2.9 h, respectively). Pharmacokinetic data of epirubicin metabolites evaluated at the first and sixth cycle of chemotherapy were superimposable without any statistical difference. CONCLUSION: Enhanced anthracycline cardiotoxicity related to trastuzumab administration was not linked to pharmacokinetic interferences with epirubicin and its metabolites.     

Epirubicin and doxorubicin comparative metabolism and pharmacokinetics

Summary The pharmacokinetics and metabolism of doxorubicin (DX) and epirubicin (epiDX) were investigated in eight cancer patients who received 60 mg/m² of both drugs independently by intravenous (i.v.) bolus at 3-week intervals according to a balanced cross-over design. Unchanged DX and epiDX plasma levels followed a triexponential decay. Half-lives (t/2) of the three decay phases were longer for DX (t/2: 4.8 vs. 3 min; t/2 2.57 h vs. 1.09 h; t/2 48.4 vs. 31.2 h). According to a model-independent analysis, the different plasma disposition kinetics of the two compounds appears to be related to a higher plasma clearance (PlCl) and to a lower mean residence time (MRT) of epiDX (PlCl: 75.0 l/h, range: 35.6–133.4 l/h; MRT: 31.6 h, range: 7.0–41.5 h;) compared to DX (PlCl: 56.8 l/h, range: 24.4–119.5; MRT: 45.6 h, range: 26.0–83.1 h). No statistically significant differences could be detected for the volume of distribution at steady state (Vss) (epiDX, 31.8 l/kg; DX, 33.3 l/kg). Metabolites common to both compounds were detected in plasma: the 13-dihydro derivatives doxorubicinol (DXol) and epirubicinol (epiDXol), together with monor amounts of four aglycones (7-deoxy adriamycinone, adriamycinone, 7-deoxy 13-dihydro adriamycinone, and 13-dihydro adriamycinone). Following epiDX administration, two additional major metabolites were detected: the glucuronic acid conjugates of epiDX (4-O--d-glucuronyl-4-epiDX) and epiDXol (4-O--d-glucuronyl 13-dihydro-4-epiDX). This additional detoxication route appears to account for the more efficient and faster elimination of epiDX than of DX. In the urine collected in the 6 days after treatment, 12.2% of the DX and 11.9% of the epiDX dose was excreted as unchanged drug and fluorescent metabolites. A comparable renal clearance was calculated for DX (4.7 l/h, range 1.4–7.0 l/h) and epiDX (4.4 l/h, range 1.7–7.0 l/h). One patient with hepatic metastates and abnormal bilirubin serum level had percutaneous biliary drainage because of extrahepatic obstruction. The elimination of both drugs was significantly impaired in this patient; nevertheless, elimination of epiDX was still more efficient and faster than that of DX (PlCl: 35.6 vs. 24.4 l/h; MRT: 39.0 vs. 83.1 h; t/2: 47 vs. 74 h). This patient's biliary excretion accounted for 35.4% of the epiDX dose and 18.2% of the DX dose.Supported in part by contract CNR, No. 85.02282.44 (Progetto Finalizzato Oncologia)     

The pharmacokinetics of epirubicin and docetaxel in combination in rats

Purpose: The aim of the present study was to investigate possible pharmacokinetic interactions between epirubicin (EPI) and docetaxel (DTX) in rats. Methods: Male Sprague Dawley rats (n = 36) were used in the study. They received either DTX (5 mg/kg, n = 9), EPI (3.5 mg/kg, n = 13), or a combination (5 mg/kg + 3.5 mg/kg, n = 14), administered as intravenous bolus doses. Blood samples were collected at various time-points between 3 min and 45 h after dose administration. DTX and EPI plasma concentrations were determined by HPLC analysis. Pharmacokinetic evaluation was carried out using the NONMEM program. Results: A three-compartment model best described the concentration-time profiles for EPI. Clearance (CL), intercompartmental clearances (Q2 and Q3), central (V1) and peripheral (V2 and V3) volumes of distribution were estimated as 3.57 l/h per kg, 5.01 l/h per kg, 12.48 l/h per kg, 0.805 l/kg, 3.67 l/kg and 158 l/kg, respectively. A two-compartment model was sufficient to describe the DTX data. CL, intercompartmental clearance (Q), V1 and V2 for DTX were estimated as 7.3 l/h per kg, 4.6 l/h per kg, 0.69 l/kg and 2.6 l/kg, respectively. No significant change in the disposition of either drug was found when they were administered in combination compared to when they were given singly. Conclusion: Concurrent treatment with EPI and DTX does not appear to cause any changes in the pharmacokinetics of the drugs in rats. Received: 3 December 1998 / Accepted: 7 April 1999     

Variability in the pharmacokinetics of epirubicin: a population analysis

Summary Population pharmacokinetic analysis of the anticancer agent epirubicin was carried out using the program NONMEM. Data were available from 36 patients aged 20–73 years, of whom 23 were women. All subjects exhibited normal liver and renal function. Epirubicin was given as a short-term i. v. infusion over the dose range of 25–100 mg/m², and an average of 11 plasma samples/subject were taken for a period of up to 72 h after each dose. A Two compartment model was fitted to the data, characterised by the parameters clearance, volume of the central compartment, alpha and beta. Clearance was tested as a linear function of various demographic and/or biochemical features. A significant proportion of the variability in clearance could be attributed to sex, and also to age in women. For example, a 25-year-old man would display an average clearance of 95 l/h, whereas a 70-year-old woman would exhibit an average clerance of 64 l/h. Such differences in clearance might be important in the selection of epirubicin dose regimens.     

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)     

高剂量与常规剂量表柔比星治疗恶性肿瘤的药物动力学研究

目的：研究高剂量与常规剂量表柔比星（表阿霉素,EPI）在肿瘤化疗患者体内的药物动力学过程,并初步探讨剂量-毒副反应相关性。方法：31例肿瘤患者分两组接受包含70mg/m^2或120mg/m^2EPI的联合化疗,高效液相色谱法（HPLC）测定血药浓度,3P87程度进行药动学房室模型数据似合和参数计算。,临床评估毒副反应,进行高剂量EPI化疗耐受性研究。结果：一次静脉应用EPI的药物动力学符合 三室模型。两种剂量EPI化疗耐受性 均良好。结论：EPI的消除符合三室模型特征,具有个体差异大、消除缓慢等特点。高剂量与常规剂量EPI相比较,主要药物动力学参数差异无显著性。     

Flow cytometric analysis of the cell cycle phase specificity of DNA damage induced by radiation, hydrogen peroxide and doxorubicin

We have optimized a flow cytometric DNA alkaline unwinding assay to increase the sensitivity in detecting low levels of DNA damage (strand breaks and alkali-labile sites) and to permit the measurement of the extent of DNA damage within each cell cycle compartment. The lowest gamma radiation dose that induced detectable DNA damage in each cell cycle phase of HeLa and CEM cells was 10 cGy. The lowest H(2)O(2) concentration that induced detectable DNA damage in each cell cycle phase was 0.5 microM in HeLa cells, and 1-2.5 TmicroM in CEM cells. For both HeLa cells and CEM cells, DNA damage in each cell cycle compartment increased approximately linearly with increasing doses of gamma radiation and H(2)O(2). Although untreated HeLa and CEM cells in S phase consistently exhibited greater DNA unwinding than did G(1) or G(2) cells (presumably due to DNA strand breaks associated with replication forks), there was no difference between the susceptibility of G(0)/G(1), S and G(2)/M phase cells to DNA damage induced by gamma radiation or H(2)O(2), or in the rate of repair of this damage. In each cell cycle phase, the susceptibility to gamma radiation-induced DNA damage was greater in CEM cells than in HeLa cells. In contrast to the lack of cell cycle phase-specific DNA damage induced by exposure to gamma radiation or H(2)O(2), the cancer chemotherapeutic drug doxorubicin (adriamycin) predominantly induced DNA damage in G(2) phase cells.