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     

Plasma and cerebrospinal fluid pharmacokinetics of cytosine arabinoside in dogs

Summary Cytosine arabinoside (ara-C) is a component of many protocols for the treatment of CNS (central nervous system) leukemia and lymphoma in humans and dogs. It is also used for the prophylaxis of CNS metastasis in acute lymphoblastic leukemia. Although ara-C enters the cerebrospinal fluid (CSF) of human cancer patients after i.v. administration, it is unclear whether a similar CNS distribution occurs in humans whose blood-brain barrier has not been compromised by invasive disease. No information on the penetration of ara-C into the CSF in dogs is available. We studied the plasma and CSF pharmacokinetics of 600 mg/m² ara-C in ten healthy male dogs after its administration as a rapid i.v. bolus (six dogs) or as a 12-h i.v. infusion (four dogs). Ara-C concentration in blood and CSF samples was determined by high-performance liquid chromatography (HPLC). After an i.v. bolus of ara-C, the mean plasma distribution half-life was 7.1±4.5 min and the mean elimination half-life was 69±28 min. The mean plasma clearance was 227±125 ml min^–1 m^–2. The peak concentration of ara-C in the CSF was 29±11 m, which occurred at 57±13 min after the ara-C bolus. The CSF elimination half-life was 113±26 min. During a 12-h infusion of ara-C (50 mg m^–2 h^–1), the plasma steady-state concentration was 14.1±4.2 m, the CSF steady-state concentration was 8.3±1.1 m, and the CSF: plasma ratio was 0.62±0.14. The plasma eleimination half-life was 64±19 min and the plasma clearance was 214±69 ml min^–1 m^–2. The CSF elimination half-life was 165±28 min. No clinically significant toxicity was observed over a 21-day period following drug administration in either of the treatment groups. Our data indicate that ara-C crosses the blood-brain barrier in normal dogs and that i.v. administration of this drug has potential as a treatment modality for neoplasia involving the CNS.Supported by the Canine Disease Research Fund and in part by the Elsa U. Pardee Foundation     

Cellular pharmacokinetics of doxorubicin in patients with chronic lymphocytic leukemia: comparison of bolus administration and continuous infusion

The purpose of this study was to determine whether administration of doxorubicin (DOX) as a continuous infusion or a bolus injection resulted in similar leukemic cell drug concentration in patients with refractory chronic lymphocytic leukemia (CLL). This study was carried out on five patients with refractory CLL, with DOX administered either as a bolus injection (35 mg/m²; CHOP protocol) or as a constant-rate infusion for a period of 96 h (9 mg/m² per day; VAD protocol). The two types of drug administration were used alternatively with the same patient. Plasma and cellular DOX concentration were determined using high-performance liquid chromatography. Peak plasma DOX levels were higher after the bolus injection than after continuous administration (1509±80 ng/ml vs 11.6±1.8 ng/ml, respectively), whereas the plasma area under the curve (AUC) levels were similar. Maximum DOX cellular concentrations were 8629±2902 ng/10⁹ cells (bolus injection) and 2745±673 ng/10⁹ cells (96 h infusion). The cellular AUC after the bolus injection was 2.85 times greater than that observed after continuous administration. This difference was due to a higher cellular peak level followed by a relatively prolonged retention of the drug, with a loss of only 25% in the first 24 h following. These findings demonstrated that in CLL the cellular DOX exposure can be notably modified by the method of drug administration, with higher drug intracellular concentrations being achieved after bolus administration than with the infusion schedule.     

Pharmacokinetics of VP16-213 given by different administration methods

Summary Plasma pharmacokinetics of VP16-213 were investigated after a 30–60 min infusion in 14 adult patients and six children. In adults the elimination half-life (T_1/2 ), plasma clearance (Cl_p) and volume of distribution (Vd) were respectively 7.05±0.67 h, 26.8±2.4 ml/min/m², and 15.7±1.8 l/m²; in children 3.37±0.5 h, 39.34±6.6 ml/min/m², and 9.97±3.7 l/m². After repeated daily doses no accumulation of VP16-213 was found in plasma. The unchanged drug found in the 24 h urine after administration amounted to 20–30% of the dose.In eight choriocarcinoma patients plasma levels of VP16-213 were measured after oral capsules and drinkable ampoules. The bioavailability compared to the i.v. route was variable, mean values being 57% for capsules and 91% for ampoules. In one further patient, with abnormal d-Xylose absorption results, VP16-213 was not detectable in plasma after the oral ampoule dose.Steady state levels investigated in three patients after 72 h continuous VP16-213 infusion (100 mg/m²/24 h) were around 2–5 g/ml. Levels of VP16-213 were undetectable in CSF after i.v. or oral administration.     

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     

Pharmacokinetic studies of 9-nitrocamptothecin on intermittent and continuous schedules of administration in patients with solid tumors

Purpose Oral administration of 9-nitrocamptothecin (9NC), and the formation of its metabolite 9-aminocamptothecin (9AC), may be associated with high interpatient and intrapatient variability. Therefore, we evaluated the plasma pharmacokinetics and urine recovery of 9NC administered on three different schedules as part of phase I and phase II studies.Experimental design In phase I schedule A, 9NC was administered orally daily for 5 days per week for 2 weeks repeated every 4 weeks. On phase I schedule B, 9NC was administered daily for 14 days repeated every 4 weeks. In Phase II, 9NC was administered daily for 5 days during 8 weeks (one cycle). Serial blood samples were obtained on day 1 and day 10 or 11 for phase I studies, and day 1 and day 50 for the phase II study. Recovery of 9NC and 9AC in urine was evaluated on day 1 and day 10 or 11 in the phase I study. Area under the 9NC and 9AC plasma concentration vs time curves from 0 to 24 h (AUC_{0–24 h}) were calculated using compartmental analysis.Results The mean±SD 9NC lactone AUC_{0–24 h} values on day 1 at the maximum tolerated dose of schedules A and B (2.43 and 1.70 mg/m², respectively) and the phase II dose (1.5 mg/m²) were 78.9±54.4, 155.7±112.8, and 48.3±17.5 ng/ml·h, respectively. The mean±SD 9AC lactone AUC_{0–24 h} values at these same doses of 9NC were 17.3±17.9, 41.3±16.6, and 31.3±12.8 ng/ml h, respectively. The ratios of 9NC lactone AUC_{0–24 h} on day 10 or 11 to day 1 on phase I A and B were 1.27±0.68 and 1.73±1.56, respectively, and the ratios 9AC lactone AUC_{0–24 h} on day 10 or 11 to day 1 on phase I A and B were 2.23±1.02 and 1.65±0.97, respectively. The recovery of 9NC and 9AC in the urine was <15%.Conclusions There was significant interpatient and intrapatient variability in the disposition of 9NC and 9AC. 9NC and 9AC undergo primarily nonrenal elimination.     

Phase I clinical and pharmacokinetic study of cyclophosphamide administered by five-day continuous intravenous infusion

Summary A total of 14 patients, 7 male and 7 female, received in all 21 evaluable courses of cyclophosphamide administered by 5-day continuous infusion. Cyclophosphamide doses were escalated from 300 to 400 mg/m² per day for 5 days and repeated every 21–28 days. The patient population had a median age of 55 years (range 38–76) and a median Karnofsky performance status of 80 (range 60–100). Only 1 patient had not received prior therapy; 5 patients had received only prior chemotherapy, 1 had received only prior radiotherapy, and 7 had received both. Tumor types were gastric (1), lung (2), colon (4), urethral adenocarcinoma (1), cervical (2), chondrosarcoma (1), melanoma (1), uterine leiomyosarcoma (1), and pancreatic (1). The dose-limiting toxicity was granulocytopenia, with median WBC nadir of 1700/l (range 100–4800) in 8 heavily pretreated patients treated at 350 mg/m² per day for 5 days. One patient without heavy prior treatment received two courses at 400 mg/m² and had WBC nadirs of 800/l and 600l. WBC nadirs occurred between days 9 and 21 (median 14). Drug-induced thrombocytopenia occurred in only one patient (350 mg/m² per day, nadir 85000/l). Neither hyponatremia nor symptomatic hypoosmolality was observed. Radiation-induced hemorrhagic cystitis may have been worsened in one patient. Nausea and vomiting were mild. Objective remissions were not observed. The maximum tolerated dose for previously treated patients is 350 mg/m² per day for 5 days. This dose approximates the doses of cyclophosphamide commonly used with bolus administration. Plasma steady-state concentrations (Css) of cyclophosphamide, measured by gas liquid chromatography, were 2.09–6.79 g/ml. Steady state was achieved in 14.5±5.9 h (mean ±SD). After the infusion, cyclophosphamide disappeared from plasma monoexponentially, with a t^1/2 of 5.3±3.6 h. The area under the curve of plasma cyclophosphamide concentrations versus time (AUC) was 543±150 g/ml h and reflected a cyclophosphamide total-body clearance (CL_TB) of 103±31.6 ml/min. Plasma alkylating activity, assessed by p-nitrobenzyl-pyridine, remained steady at 1.6–4.3 g/ml nor-nitrogen mustard equivalents. Urinary excretion of cyclophosphamide and alkylating activity accounted for 9.3%±7.6% and 15.1%±2.0% of the administered daily dose, respectively. The t^1/2 and AUC of cyclophosphamide associated with the 5-day continuous infusion schedule are similar to those reported after administration of cyclophosphamide 1500 mg/m² as an i.v. bolus. The AUC of alkylating activity associated with the 5-day continuous infusion of cyclophosphamide is about three times greater than the AUC of alkylating activity calculated after a 1500-mg/m² bolus dose of cyclophosphamide. Daily urinary excretions of cyclophosphamide and alkylating activity associated with the 5-day continuous infusion schedule are similar to those reported after bolus doses of cyclophosphamide.     

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 3-deazaguanine

Summary 3-Deazaguanine (3DG), an antipurine antimetabolite, has recently completed a phase I clinical trial at this Institute. The drug was given on a dailyx5 schedule by i.v. infusion over 0.25–2.16 h. The pharmacokinetics of 3DG during 16 courses were studied in 12 patients at doses of 200–800 mg/m². 3DG in plasma was measured by an isocratic reverse-phase high-performance liquid chromatographic (HPLC) procedure carried out on IBM phenyl columns at 40° C using 10mM phosphate buffer (pH 7) as the mobile phase and detection at 300 nm. Plasma decay of 3DG was biexponential in all patients. The AUC correlated linearly with dose at 200–600 mg/m² but deviated from linearity at doses>600 mg/m². The drug was cleared rapidly from plasma; at doses of 200–600 mg/m², the mean plasma clearance was 61.64±9.97 l/h and the mean terminal-phase elimination half-life was 1.6±0.6 h. The steady-state volume of distribution (98.8±29.1 l) and distribution coefficient (1.24±0.39 l/kg) indicated extensive tissue distribution for the drug. No statistically significant difference was observed between the pharmacokinetics of 3DG on day 1 and that on day 4 as evaluated in three patients for whom complete plasma data were available on both days.     

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 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.     

Tumor-tissue and plasma concentrations of platinum during chemotherapy of non-small-cell lung cancer patients

Summary Tumor-tissue and plasma concentrations of platinum were studied prospectively in two groups of eight patients who were suffering from advanced non-small-cell lung cancer. Treatments including two different schedules of cisplatin administration (25 vs 100 mg/m² on day 1) were compared. At 30 min after the beginning of the cisplatin infusion, blood samples and bronchoscopically obtained biopsy specimens were taken for determinations of platinum concentrations by means of flameless atomic absorption spectrophotometry. The procedure did not induce any complication. Total plasma platinum concentrations at 30 min were significantly lower (P<0.01) in patients receiving 25 mg/m² (0.49±0.23 g Pt/ml) than in those receiving 100 mg/m² (1.44±0.62 g Pt/ml), whereas no significant difference was observed in tumor-tissue platinum concentrations (22.49±53.89 ng Pt/mg in patients receiving 25 mg/m² vs 51.13±65.52 ng Pt/mg in those receiving 100 mg/m²). There was a weak correlation between simultaneous plasma and tumor-tissue platinum concentrations at 30 min. Tumor-tissue platinum concentrations seem to be poorly influenced by the cisplatin dose. This finding suggests a great interindividual variability of platinum tumor-diffusion properties in non-small-cell lung cancer.Supported in part by a grant from the Ligue Nationale Française contre le Cancer     

Phase I and pharmacokinetic studies with the pentacyclic pyrroloquinone mitoquidone

Summary Mitoquidone (MTQ) is the first member of a new group of pentacyclic pyrroloquinones developed for clinical evaluation as a potential anticancer agent. MTQ demonstrated good activity in a range of experimental solid tumour models, but was weakly active against standard prescreens such as the P388 murine leukaemia. Bone marrow suppression or other significant toxicity was not observed in preclinical studies. Twenty-seven patients were treated with MTQ given as a 4-h infusion either once every 21 days (150–600 mg/m²), once a week (200 mg/m² per week), or as 5 daily doses repeated every 28 days (60–180 mg/m² per day). The major adverse events encountered included nausea and vomiting (in virtually all patients), dyspnoea, tumour-related pain, and thrombocytopenia in several patients with pretreatment bone-marrow impairment. Phase I studies were suspended without a maximum tolerated dose being reached because of formulation difficulties. There were no major responses, although stable disease was observed in a number of patients with gastrointestinal malignancies. Temporary remission of B-symptoms occurred in two patients with lymphoma. The plasma pharmacokinetics of MTQ were investigated using an HPLC assay with fluorescence detection. Linear pharmacokinetics were observed with a terminal plasma half-life of 2.9±2.1 h (n=18 doses). The volume of distribution was 3.4±2.6 l/kg and plasma clearance was 629±469 ml/min per m². Several soluble analogues with similar antitumour activity are currently under investigation.This work was supported by Glaxo Group Research Ltd., Greenford, UK     

Clinical pharmacokinetics of carboplatin in children

The present study was undertaken to evaluate in children the plasma pharmacokinetics of free carboplatin given at different doses and schedules and to evaluate the inter- and intrapatient variability and the possible influence of schedule on drug exposure. A total of 35 children (age range, 1–17 years) with malignant tumors were studied. All patients had normal renal function (creatinine clearance corrected for surface body area, above 70 ml min^–1 m^–2; range, 71–151 ml min^–1 m^–2) and none had renal involvement by malignancy. Carboplatin was given at the following doses and schedules: 175, 400, 500, and 600 mg/m² given as a 1-h infusion; 1,200 mg/m² divided into equal doses and infused over 1 h on 2 consecutive days; and 875 and 1,200 mg/m² given as a 5-day continuous infusion. A total of 57 courses were studied. Carboplatin levels in plasma ultrafiltrate (UF) samples were measured both by high-performance liquid chromatography and by atomic absorption spectrophotometry. Following a 1-h infusion, carboplatin free plasma levels decayed biphasically; the disappearance half-lives, total body clearance, and apparent volume of distribution were similar for different doses. In children with normal renal function as defined by creatinemia and blood urea nitrogen (BUN) and creatinine clearance, we found at each dose studied a limited interpatient variability of the peak plasma concentration (C_max) and the area under the concentration-time curve (AUC) and a linear correlation between the dose and both C_max (r=0.95) and AUC (r=0.97). The mean value ± SD for the dose-normalized AUC was 13±2 min m² l^–1 (n=57). The administration schedule does not seem to influence drug exposure, since prolonged i.v. infusion or bolus administration of 1,200 mg/m² achieved a similar AUC (13.78±2.90 and 15.05±1.44 mg ml^–1 min, respectively). In the nine children studied during subsequent courses a limited interpatient variability was observed and no correlation (r=0.035) was found between AUC and subsequent courses by a multivariate analysis of dose, AUC, and course number. The pharmacokinetic parameters were similar to those previously reported in adults; however, a weak correlation (r=0.52,P=0.03) between carboplatin total body clearance and creatinine clearance varying within the normal range was observed. A dosing formula appears unnecessary in children with normal renal function since a generally well-predictable free carboplatin AUC is achieved following a given dose.Supported by the Associazione Italiana per la Ricerca sul Cancro (A.I.R.C.)     

Oxaliplatin added to 5-fluorouracil-based therapy (5-FU +/- FA) in the treatment of 5-FU-pretreated patients with advanced colorectal carcinoma (ACRC): results from the European compassionate-use program.

Purpose: To provide evidence for the therapeutic efficacy of oxaliplatin (Eloxatin®) when given as a 2–6-hour i.v. infusion, alone or in combination with 5-fluorouracil/folinic acid (5-FU ± FA) in patients with advanced colorectal carcinoma (ACRC) who have failed 5-FU-based therapy. To confirm the safety of the drug and its combination in an extended-access context.Patients and methods: Prescribing physicians were supplied oxaliplatin on a nominative compassionate-use basis, after obtaining informed consent. Europe-wide, 206 ACRC patients in 44 centers received 1168 cycles of chemotherapy with oxaliplatin (80–100 mg/m² q 2 weeks or 100–135 mg/m² q 3 weeks) delivered as a short (2–6 hours) i.v. infusion, 177 of them (1026 cycles) receiving oxaliplatin + 5-FU ± FA.Results: Oxaliplatin added to the 5-FU ± FA regimens of 111 verified 5-FU-refractory patients (imaging and/or clinical proof of progression under prior 5-FU-based regimen), elicited objective responses in 25 of 98 evaluable patients, (ORR: 25.5%, 95% confidence interval (95% CI: 17–35). The median time to progression was 4.1 months (95% CI: 3.3–5.0) and the median overall survival was 9.6 months (95% CI: 8.2–10.9). Differences in the toxicity profile of the oxaliplatin + 5-FU ± FA combination appear related to administration modality, dose and schedule of the 5-FU-based regimen.Conclusions: The addition of oxaliplatin (2–6-hour i.v. infusion) to 5-FU ± FA regimens is active in ACRC patients with clinical resistance to fluoropyrimidines. The therapeutic index of oxaliplatin + 5-FU ± FA combinations administered as salvage therapy compares favorably with those reported in recent phase II–III trials involving other new agents or combinations active in 5-FU-refractory ACRC patients.     

Pharmacokinetics of high-dose busulfan in children

Summary The pharmacokinetics of high-dose busulfan given orally at 1 mg/kg every 6 h over 4 days (total dose, 16 mg/kg) in combined chemotherapy followed by autologous bone marrow transplantation was studied in 12 children with a mean age of 7 years (range, 4–14 years). Busulfan levels in biological fluids were measured by a gas chromatographic assay with mass fragmentographic detection, using a deuterated analogue as the internal standard. In a high-dose regimen, busulfan followed one-compartment model kinetics with zero-order absorption. A mean maximal concentration of 803±228 ng/ml was achieved at 92–255 min after dosing. The mean elimination half-life was 2.33 h, and the mean total clearance was 119±54 ml/min per m², with an apparent distribution volume of 27.10±11.50 l/m². A mean trough level of 370 ng/ml was found throughout the 4 days of the chemotherapy course. There were no significant variations in pharmacokinetic parameters measured after the first and last doses. Busulfan was monitored in the CSF of nine children at 3.25–7 h after the last dose and was detected in all patients, with a mean CSF-to-plasma concentration ratio of 0.95 (range, 0.5–1.4).     

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.     

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.     

A phase I and pharmacokinetics study of prolonged ambulatory-infusion carboplatin

A total of 18 patients received 6-week ambulatory infusions of carboplatin in groups at dose levels of 14, 28, 35 and 42 mg/m² per day. The dose-limiting toxicity was myelosuppression. At 42 mg/m², three of four patients had WHO grade 4 and one of four had grade 3 neutropenia, whereas two patients had grade 3 thrombocytopenia. At 35 mg/m², two of five patients had grade 3 neutropenia, whereas one had grade 4 and two had grade 3 thrombocytopenia. Non-hematological toxicities were predominantly gastrointestinal, with 3 of 18 patients experiencing grade 3 emesis. Total and ultrafiltrable platinum (UFPt) were assayed by flameless atomic absorption spectrometry in weekly and post-infusion plasma and urine samples. In plasma, levels of total platinum increased throughout the infusion, and the protein binding slowly increased from 60% platinum bound at week 1 to 90% bound by week 4. Although the UFPt level reached a steady state within 1 week, the concentration did not increase with the dose level, remaining at a mean value of 0.58±0.24 M. Renal excretion of platinum accounted for 70±12% of the dose at steady state. There was a high inter-patient variability in both total body clearance of UFPt (range, 83–603 ml/min) and renal clearance (range, 67–390 ml/min). A terminal elemination half-life of 13–27 h was noted for post-infusion UFPt. Neutropenia was linearly related to the total daily carboplatin dose, but neither neutropenia nor thrombocytopenia could be related to steady-state UFPt or the UFPt area under the concentration-time curve (AUC). The recommended dose for phase II studies is 28 mg/m² per day.     

Cellular and plasma adriamycin concentrations in long-term infusion therapy of leukemia patients

Summary To determine whether long-term adriamycin (ADM) infusions resulted in cellular ADM concentrations at least comparable to those observed after bolus injections, ADM cellular and plasma concentrations were measured in 18 patients with leukemia. ADM was administered at 30 mg/m² per day for 3 days, either as bolus injections or as 4-, 8-, or 72-h infusions. Negligible accumulation of plasma ADM was observed. Peak plasma ADM concentrations after bolus injections were 1640±470 ng/ml (n=7). Maximum levels were 176±34 ng/ml during 4-h infusion (n=5); 85±50 ng/ml during 8-h infusion (n=4); and 47±5 ng/ml (n=2) after 72-h infusion. ADM concentrations in nucleated blood and bone marrow cells correlated well (r=0.82, n=47). ADM accumulated in leukemic cells up to 30–100 times the plasma concentrations. The shorter the administration time-span, the higher the peak leukemic cell concentration and the greater the loss of drug immediately after the end of the administration. The final cellular ADM half-life was approximately 85–110 h. After long-term infusion and bolus injection of the same dose, similar areas under the curve for plasma or leukemic blast cell ADM concentrations were attained. Since comparable therapeutic efficacy was observed in all regimens, the antileukemic effect appeared not to be related to the peak plasma concentrations, while acute toxicity phenomena decreased with increasing duration of the infusion. Long-term ADM infusion deserves more attention in the treatment of patients with anthracyclines.Supported by the Queen Wilhelmina Foundation (The Netherlands Cancer Foundation, grant SNUKC 82-7), The Ank van Vlissingen Foundation and The Maurits and Anna de Kock Foundation