Leukemic cell and plasma daunomycin concentrations after bolus injection and 72 h infusion

Summary The effect of the duration of daunomycin (DNM) infusion on leukemic cell drug concentrations was evaluated. Cellular and plasma DNM concentrations were measured in 20 patients with acute non-lymphocytic leukemia. DNM 45 mg/m² was administered either as a bolus injection or as a 4-, 8- or 72-h constant-rate infusion during 3 consecutive days. Peak plasma DNM levels amounted to 227±116 ng/ml after bolus injection and were only 16±6 ng/ml after 72-h DNM infusions. Terminal plasma DNM half-lives were 14±4 h. Peak leukemic cell DNM concentrations at the 3rd day of administration were 16810±2580 ng/10⁹ cells (bolus injections) and 10310±5510 ng/10⁹ cells (72-h infusions). The areas under the cellular curve were similar and independent of the duration of the DNM infusion. Peak leukemic cell daunomycinol (DNMol) concentrations were respectively 3500 ± 1600 ng/10⁹ cells and 2850±1720 ng/10⁹ cells. Cellular DNM terminal half-life was 13±4 h. DNM concentrations in nucleated blood and bone marrow cells correlated well (r=0.93, n=26). Long-term infusion produced less severe side effects. Therapeutic efficacy was maintained during long-term infusion.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     

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     

Doxorubicin and doxorubicinol pharmacokinetics and tissue concentrations following bolus injection and continuous infusion of doxorubicin in the rabbit

Cumulative dose-related, chronic cardiotoxicity is a serious clinical complication of anthracycline therapy. Clinical and animal studies have demonstrated that continuous infusion, compared to bolus injection of doxorubicin, decreases the risk of cardiotoxicity. Continuous infusion of doxorubicin may result in decreased cardiac tissue concentrations of anthracyclines, including the primary metabolite doxorubicinol, which may also be an important contributor to cardiotoxicity. In this study, doxorubicin and doxorubicinol plasma pharmacokinetics and tissue concentrations were compared in New Zealand white rabbits following intravenous administration of doxorubicin (5 mg·kg^–1) by bolus and continuous infusion. Blood samples were obtained over a 72-h period after doxorubicin administration to determine plasma doxorubicin and doxorubicinol concentrations. Rabbits were killed 7 days after the completion of doxorubicin administration and tissue concentrations of doxorubicin and doxorubicinol in heart, kidney, liver, and skeletal muscle were measured. In further experiments, rabbits were killed 1 h after bolus injection of doxorubicin and at the completion of a 24-h doxorubicin infusion (anticipated times of maximum heart anthracycline concentrations) to compare cardiac concentrations of doxorubicin and doxorubicinol following both methods of administration. Peak plasma concentrations of doxorubicin (1739±265 vs 100±10 ng·ml^–1) and doxorubicinol (78±3 vs 16±3 ng·ml^–1) were significantly higher following bolus than infusion dosing. In addition, elimination half-life of doxorubicinol was increased following infusion. However, other plasma pharmacokinetic parameters for doxorubicin and doxorubicinol, including AUC, were similar following both methods of doxorubicin administration. Peak left ventricular tissue concentrations of doxorubicin (16.92±0.9 vs 3.59±0.72 g·g^–1 tissue;P<0.001) and doxorubicinol (0.24±0.02 vs 0.09±0.01 g·g^–1 tissue;P<0.01) following bolus injection of doxorubicin were significantly higher than those following infusion administration. Tissue concentrations of parent drug and metabolite in bolus and infusion groups were similar 7 days after dosing. The results suggest that cardioprotection following doxorubicin infusion may be related to attenuation of the peak plasma or cardiac concentrations of doxorubicin and/or doxorubicinol.     

Phase I and pharmacokinetics studies of prochlorperazine 2-h i.v. infusion as a doxorubicin-efflux blocker

In an earlier phase I study, we reported that the maximal tolerated dose (MTD) of prochlorperazine (PCZ) given as a 15-min i.v. infusion was 75 mg/m². The highest peak plasma PCZ concentration achieved was 1100 ng/ml. The present study was conducted to determine if PCZ levels high enough to block doxorubicin (DOX) efflux in vitro could be achieved and sustained in vivo by increasing the duration of i.v. infusion from 15 min to 2 h. The treatment schedule consisted of i.v. prehydration with at least 500 ml normal saline (NS) and administration of a fixed standard dose of 60 mg/m² DOX as an i.v. bolus over 15 min followed by i.v. doses of 75, 105, 135, or 180 mg/m² PCZ in 250 ml NS over 2 h. The hematologic toxicities attributable to DOX were as expected and independent of the PCZ dose. Toxicities attributable to PCZ were sedation, dryness of mouth, anxiety, akathisia, hypotension, cramps, and confusion. The MTD of PCZ was 180 mg/m². Large interpatient variation in peak PCZ plasma levels (91–3215 ng/ml) was seen, with the plasma half-life (t1/2) being approximately 57 min in patients given 135–180 mg/m² PCZ. The volume of distribution (V_d), total clearance (Cl_T), and area under the curve (AUC) were 350.1±183.8 l/m², 260.7±142.7 l m² h^–1 and 1539±922 ng ml h^–1, respectively, in patients given 180 mg/m² PCZ and the respective values for patients receiving 135 mg/m² were 48.9±23.76 l/m², 33.2±2.62 l m² h^–1, and 4117±302 ng ml h^–1. High PCZ plasma levels (>600 ng/ml) were sustained in all patients treated with 135 mg/m² PCZ for up to 24 h. DOX plasma elimination was biphasic at 135 and 180 mg/m² PCZ, and a>10-ng/ml DOX plasma level was maintained for 24 h. Partial responses were seen in three of six patients with malignant mesothelioma, in two of ten patients with non-small-cell lung carcinoma, and in the single patient with hepatoma. Our data show that PCZ can be safely given as a 2-h infusion at 135 mg/m² with clinically manageable toxicities. The antitumor activity of the combination of DOX and PCZ needs to be confirmed in phase II trials.This work was supported by NIH grant R01 CA-29360 and S1488, CRC grant M01 RR-05280, and the Joan Levy Cancer Foundation. This paper was presented at the meeting of the American Association for Cancer Research, Orlando, Florida, May 19–22, 1993     

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.     

Five-day continuous infusion of vindesine in the treatment of non-small cell lung cancer--clinical pharmacokinetics of vindesine]

We administered vindesine (VDS) as a single agent at a dose of 1.2 mg/m2/day for 5 days by continuous infusion in 6 patients with inoperable non-small cell lung cancer, and studied the pharmacokinetics of VDS. The maximum concentration (Cmax) of VDS was 6.9 ng/ml and the area under the curve (AUC) was 803 ng.hr/ml. The AUC achieved for VDS was 2.5 times higher after continuous infusion than that observed when 3 mg/m2 of VDS was given by bolus iv injection. Among six patients were 2 PR, including one PR achieved using a 5-day continuous infusion of VDS after failure to respond to cisplatin plus VDS (bolus injection). Severe leukopenia was observed, but it was clinically manageable. The AUC exposure of VDS is greater with the longer infusion periods, and this might improve efficacy compared to conventional bolus injection treatments. The need for further studies appears warranted.     

Pharmacokinetics of vindesine bolus and infusion

Summary The pharmacokinetics of vindesine were investigated during treatment of 15 patients with progressive malignancies refractory to conventional treatment. Patients were administered one of three IV dose schedules: 3.0 mg/m² bolus injection, 1.2 mg/m²/day infusion for 5 days, or 2.0 mg/m²/day infusion for 2 days. Concentrations of the drug in the serum and urine were determined by radioimmunoassay. Serum concentrations were highest (5×10^-7 M) in patients receiving a bolus injection, but fell to nondetectable levels by 48 h in four of five patients (terminal t_1/2 15.0±9.4 h). Compared with bolus injection, 1.2-to 1.4-fold greater areas under the blood concentration curve were observed during infusions of 2.0 mg/m² and 1.2 mg/m². Whereas steady-state concentrations (1×10^-8 M) were maintained throughout the infusion of 1.2 mg/m²/day progressively increasing serum levels were observed during the infusion of 2.0 mg/m²/day. Serum concentrations fell rapidly following discontinuation of the 2.0-mg/m² infusion, but were somewhat more sustained in the 1.2-mg/m² infusion group. The average urinary excretion was similar for each dose-schedule (8%–11% of the total dose). The pharmacokinetics of vindesine are influenced by variations in dose schedule.     

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     

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.)     

Plasma and tumor concentrations of cisplatin following intraperitoneal infusion or bolus injection with or without continuous low-dose-rate irradiation

Our purpose of this study was to determine whether whole-body, continuous low-dose-rate irradiation (CLDRI) alters the plasma and/or tumor platinum pharmacokinetics after ip bolus injection or ip infusion as a possible mechanism of interaction between CLDRI and cisplatin. The C3Hf/Sed mice bearing SCCVII/SF tumors were given 6 mg cisplatin/kg ip by bolus injection or an ip infusion of 0.25 mg cisplatin.kg-1.hour-1 for 48 hours with and without CLDRI at 0.56 Gy/hr for 24 or 48 hours. Plasma and tumor platinum concentrations were determined with an atomic absorption spectrophotometer at appropriate intervals during infusion and up to 48 hours after drug administration. Both total and ultrafilterable plasma platinum followed a biphasic elimination after ip bolus injection, whereas only a prolonged single-phase elimination was seen after ip infusion. Tumor uptake of platinum appeared to follow a passive diffusion pattern with a prolonged cellular retention of platinum. Whole-body CLDRI had no apparent effect on the pharmacokinetics of plasma and tumor platinum administered by ip bolus injection or prolonged continuous infusion.     

Pharmacokinetics and tumor concentration of intraarterial and intravenous cisplatin in patients with head and neck squamous cancer

Summary Tumor-tissue platinum levels and major pharmacokinetic parameters were determined in 11 patients with head and neck squamous cancer (HNSC) who were given cisplatin (50 mg/m² daily x 2 days) and 5-fluorouracil (5-FU; 1000 mg/m², continuous infusion x 5 days) either i.a. or i.v. The plasma peak platinum concentrations (c _max) and the areas under the curve for total platinum concentration versus time (AUC) during i.a. infusions were lower than the i.v.c _max (mean, 1.92±0.28 and 4.08±2.80 mg/l, for i.a. and i.v. infusions, respectively) and AUC values (mean, 22.55±4.96 and 40.66±10.71 mg h^–1 l^–1 for i.a. and i.v. treatment, respectively), suggesting a first-passage extraction of the drug by the tumor mass during i.a. infusion. However, no statistically significant difference was found in platinum tumor concentrations after i.a. administration versus i.v. infusion. The lack of a difference in tumor platinum concentrations between the i.a. and the i.v. administration routes might be explained either by a relatively high blood supply to the tumor area, enabling efflux of the surplus free platinum from the tissue, or by the delay between drug infusion and biopsy. After three cycles of i.a. treatment good tumor remission was obtained with minimal local toxicity. Larger clinical studies testing the advantages of the i.a. administration route over i.v. infusion appear to be necessary.Abbreviations HNSC head and neck squamous cancer - AUC area under the total platinum concentration versus time curve - OS overall survival - 5-FU 5-fluorouracil - DFS disease-free survival - CR complete response - PR partial response - SD stable disease - PRO progression This study was supported by grants from the AIRC (Italian Association for Cancer Research) and by grant from the Regione Veneto. One of the Authors (P.A.) is the recipient of an MPI 40% grant     

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.     

Effect of phenytoin on the pharmacokinetics of doxorubicin and doxorubicinol in the rabbit

Summary Doxorubicin is metabolized extensively to doxorubicinol by the ubiquitous aldoketoreductase enzymes. The extent of conversion to this alcohol metabolite is important since doxorubicinol may be the major contributor to cardiotoxicity. Aldoketoreductases are inhibited in vitro by phenytoin. The present study was conducted to examine the effect of phenytoin on doxorubicin pharmacokinetics. Doxorubicin single-dose pharmacokinetic studies were performed in 10 New Zealand White rabbits after pretreatment with phenytoin or phenytoin vehicle (control) infusions in crossover fashion with 4–6 weeks between studies. Infusions were commenced 16 h before and during the course of the doxorubicin pharmacokinetic studies. Phenytoin infusion was guided by plasma phenytoin estimation to maintain total plasma concentrations between 20 and 30 g/ml. Following doxorubicin 5 mg/kg by i.v. bolus, blood samples were obtained at intervals over 32 h. Plasma doxorubicin and doxorubicinol concentrations were measured by HPLC. The mean plasma phenytoin concentrations ranged from 17.4 to 33.9 g/ml. Phenytoin infusion did not alter doxorubicin pharmacokinetics. The elimination half-life and volume of distribution were almost identical to control. Clearance of doxorubicin during phenytoin administration (60.9±5.8 ml/min per kg, mean±SE) was similar to that during vehicle infusion (67.5±5.4 ml/min per kg). Phenytoin administration was associated with a significant decrease in doxorubicinol elimination half-life from 41.0±4.8 to 25.6±2.8 h. The area under the plasma concentration/time curve (AUC) for doxorubicinol decreased significantly from 666.8±100.4 to 491.5±65.7 n.h.ml^-1. These data suggest that phenytoin at clinically relevant concentrations does not alter the conversion of doxorubicin to doxorubicinol in the rabbit. The reduction in the AUC for doxorubicinol caused by phenytoin appears to be due to an increased rate of doxorubicinol elimination. Phenytoin or similar agents may have the effect of modifying doxorubicinol plasma concentrations by induction of doxorubicinol metabolism rather than by inhibition of aldoketoreductase enzymes.     

High-dose idarubicin in combination with Ara-C in patients with relapsed or refractory acute lymphoblastic leukemia: a pharmacokinetic and clinical study

Objective High dose (HD) Ara-C combined with a single HD idarubicin dose (IDA) is an efficient and safe salvage regimen for patients with refractory or relapsed acute lymphoblastic leukemia as indicated by phase II studies. No data are available on the pharmacokinetics of IDA after a rapid HD intravenous infusion. An open phase II pharmacokinetic and clinical study was performed to evaluate antileukemic efficacy, IDA pharmacokinetics and to investigate the presence of IDA and its reduced metabolite idarubicinol (IDAol) in cerebrospinal fluid (CSF) of patients treated with HD-IDA. Patients and methods Twenty-five patients with refractory or relapsed acute lymphoblastic leukemia received Ara-C 3 g/m² from days 1–5, idarubicin (HD-IDA) 40 mg/m² as rapid intravenous (i.v.) infusion on day 3 and subcutaneous G-CSF 5 μg/kg from day 7 until PMN recovery. Pharmacokinetics of IDA was evaluated after HD idarubicin administration in nine of these patients. CSF samples were collected in 15 patients at different times. IDA and IDAol concentrations were quantified by a validated HPLC assay described in detail elsewhere. Results Eleven patients (44%, 95% CI: 23–65%) achieved complete remission with median disease free survival for 6 months. After administration of HD-IDA i.v. bolus of 40 mg/m², plasma level profiles of unchanged drug and IDAol were similar to those previously described after standard dose and measured with the same analytical method. The mean terminal half-life measured for IDA in this group of patients (14.9 h) was not significantly different from the mean value observed after standard dose (13.9 h, P = 0.72). IDAol t _1/2 was also similar after HD-IDA (46.2 h) and standard dose (39.4 h, P = 0.79). Pharmacokinetic data reveal that in our series of patients IDA and IDAol clearances are significantly higher than those observed in patients treated with 12 mg/m² of IDA but, although the administered dose (mg/m²) of the drug is 3.3 times higher, IDA exposure (measured in terms of AUC) is only 2.3 times and IDAol exposition 2.1 times greater. Furthermore, HD infusion resulted in a ratio between the AUC of parent drug and idarubicinol not different from the value observed with the standard-dose. IDA and IDAol were measurable only in 3 of the 15 cerebrospinal fluid samples collected. Conclusion Responses observed in our series are comparable to those reported with other salvage regimens. The IDA exposure lower than expected may explain the safety of the single i.v. administration of 40 mg/m² of IDA, combined with HD Ara-C, with a degree of myelosuppression equivalent to that reported with this agent administered in standard doses. Our data do not allow us to clearly attribute this behavior to a pharmacokinetic non-linearity since the baseline creatinine clearance, even within normal values, and patient age are significantly different in the two groups. Cerebrospinal fluid penetration was poor, reaching levels not considered as cytotoxic. The authors declare that they have no potential conflict of interest.     

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     

The effect of food on oral melphalan absorption

Summary Fifteen patients receiving oral melphalan (4.2–5.3 mg/m²) for a variety of neoplastic disorders were studied. Ten patients received the drug on separate occasions, with and without a standardized breakfast. Eight of these patients also received an IV bolus dose (5 mg/m²) to determine bioavailability. Serial melphalan plasma samples were taken over 5 h after administration and assayed by high-performance liquid chromatography. The median area under the curve (AUC) when taken fasting was 179 (range 95–336) ng · h · ml^-1, and when taken with food, 122 (47–227) ng · h · ml^-1, the median reduction being 39% (P0.01). In one patient, who died before completing the study, the drug was not detectable at all after being taken with food. In the eight patients who were also given IV melphalan, the median terminal melphalan half-life (57 min, range 38–71) was no different from its oral half-life [55 (27–104) min fasting; 55 (30–72) min with food] (P>0.1). In these patients bioavailability was 85% (26–96)% when the drug was taken fasting and 58% (7–99)% when taken with food (P0.025). Median clearance following IV administration was 362 ml/min/m² (range 104–694). It was found that the melphalan level in a single plasma sample drawn 1.5 h after administration was highly predictive of oral melphalan AUC (r_s=0.915, P0.1). This study suggests that to ensure optimum absorption of the drug, melphalan should not be taken with food.     

Phase I and pharmacokinetic trial of liposome-encapsulated doxorubicin

A total of 21 patients with advanced cancer were entered into a phase I study to determine the maximum tolerable dose (MTD) of liposome-encapsulated doxorubicin (LED) given weekly for 3 consecutive weeks at doses of 20, 30, or 37.5 mg/m² per week. For a comparison of the pharmacokinetic behavior of LED with that of standard-formulation doxorubicin, 13 patients received a dose of standard-formulation doxorubicin 2 weeks prior to the first dose of LED. All doses were given by 1-h infusion through a central vein. Toxicity was evaluated in 22 courses delivered to 17 patients. The MTD with this schedule was 30 mg/m² per week×3. The single patient treated at 37.5 mg/m² weekly could not complete the entire course due to myelosuppression. At the dose of 30 mg/m² per week, three of eight patients had grade 3 leukopenia. Other toxicities included mild to moderate thrombocytopenia, nausea, vomiting, fever, alopecia, diarrhea, fatigue, stomatitis, and infection. At the dose of 30 mg/m² per week, the total doxorubicin AUC and peak total doxorubicin concentrations in plasma were 8.75±8.80 M h (mean±SD) and 3.07±1.45 M, respectively, after LED administration. The total doxorubicin AUC and peak total doxorubicin concentrations in plasma were 3.92±2.47 M h and 2.75±2.70 M, respectively, after the infusion of standard-formulation doxorubicin. The total body clearance of doxorubicin was 18.42±11.23 l/h after the infusion of LED and 31.21±15.48 l/h after the infusion of standard-formulation doxorubicin. The mean elimination half-lives of doxorubicin were similar: 8.65±5.16 h for LED and 7.46±5.16 h for standard-formulation doxorubicin. Interpatient variability in pharmacokinetic parameters as demonstrated by the percentage of coefficients of variation was 33%–105%. There was no relationship between the percentage of WBC decrease or the duration of WBC suppression and the total doxorubicin or doxorubicinol AUC. There was no correlation between the duration of leukopenia and drug exposure as reflected by the AUC of liposome-associated doxorubicin. LED can be given in doses similar to those of standard-formulation doxorubicin and produces acute toxicities similar to those caused by standard doxorubicin.Abbreviations MTD maximum tolerable dose - LED liposome-encapsulated doxorubicin - AUC area under the plasma concentration x time curve - WBC white blood cell count - PLT platelet count - ECOG Eastern Cooperative Oncology Group - EKG electrocardiogram - MUGA multigated nuclide scan - CLTB total body clearance - PC phosphatidylcholine: PG, phosphatidylglycerol - PEG-DSPE polyethylene glycol conjugated to distearoyl phosphatidylethanolamine - HSPC hydrogenated soy phosphatidylcholine - chol cholesterol This work was supported by DHHS, NCl NO-l-CM 07 303 and by a Career Development Award from the American Cancer Society (to B. A. C.)     

A phase I trial of high-dose continuous-infusion hydroxyurea

Hydroxyurea inhibits ribonucleotide reductase, resulting in depletion of intracellular deoxynucleotide pools and inhibition of DNA repair. It has been used in a variety of malignancies and is usually given orally. Deoxynucleotide depletion is directly related to the concentration of and duration of exposure to hydroxyurea; thus, prolonged continuous infusion may result in increased therapeutic efficacy. A total of 30 patients were treated on this trial, designed to determine the maximum tolerated, doses (MTD) of intravenous hydroxyurea given as a 24-or 48-h continuous infusion. The MTD for the 24-h infusion was 13,520 mg/m² following a bolus of 1,690 mg/m², and the mean (±SD) plasma steady-state concentration was 1.93±0.52 mM. For the 48-h infusion, the MTD was 17,576 mg/m² following a bolus of 2,197 mg/m² and the mean steady-state level was 1.43±0.31 mM. The doselimiting toxicity on both schedules was marrow suppression manifesting as, neutropenia and thrombocytopenia. Pharmacokinetic analysis revealed decreasing clearance with increasing dose, implying that drug elimination is saturable. Pharmacodynamic analysis showed a slight correlation between steady-state plasma levels and the degree of marrow suppression.This work was supported in part by grants 5T32-CA-09307, P30-A-14236-18, and 5-R01-CA45529 from the National Institutes of Health and the National Cancer Institute and by the P.B. Cohen Memorial Fund     

A limited sampling strategy for estimation of the cladribine plasma area under the concentration versus time curve after intermittent i.v. infusion,s.c. injection,and oral administration

 Cladribine is a newly developed antimetabolite with promising activity in lymphoproliferative disorders. Recent pharmacokinetics investigations have suggested that there is a relationship between its plasma area under the concentration versus time curve (AUC) and the degree of neutropenia posttreatment as well as the therapeutic outcome in hairy-cell leukemia. To enable a simple estimation of the plasma AUC, a limited sampling strategy was developed. Stepwise linear regression was used to determine which were the most important data points for estimation of the plasma AUC after 2-h i.v. infusion, s.c. injection (5 mg/m²), and oral administration (10 mg/m²) in 27 patients. The most important data points after i.v. infusion in 12 patients were 1, 4, and 24 h, in order of importance. The AUC could be estimated as 2.9081×C _1h ⁺5.1851×C _4h ⁺20.3265×C _24h .The accuracy and precision (mean value±SD for the determined/estimated AUC was 0.99±0.053) of the model could not be increased by the addition of more data points. A somewhat lower accuracy and precision (0.96± 0.089) was seen with the 2-, 4-, and 24-h data points. These were used to test the regression technique prospectively for the estimation of the AUC after i.v. administration in another set of 10 patients. The accuracy and precision of the estimation of the AUC was similar in this group (1.01±0.109). In all, 11 patients were treated orally (10 mg/m²) and 10 patients were treated by s.c. injection (5 mg/m²). The most important data points for estimation of the AUC were 2.5, 24, and 0.5 h after oral administration (AUC=0.8630×C _0.5 h+ 4.2337×C _2.5h ⁺45.4364×C _24h ) and 9, 1, and 16 h after s.c. injection (AUC=1.8821×C _1h +16.4256×C _9h ⁺ 25.4518×C _16h ). The accuracy and precision were 1.01±0.064 after oral dosing and 0.99±0.11 after s.c. injection. The derived mathematical models are reliable for estimation of the plasma AUC of cladribine after 2-h i.v. infusion, oral administration, and s.c. injection. Received: 8 October 1995/Accepted: 1 March 1996     

Quantitative relationship between pharmacokinetics of unchanged cisplatin and nephrotoxicity in rats: importance of area under the concentration-time curve (AUC) as the major toxicodynamic determinant in vivo

 Purpose: The major pharmacokinetic parameters of unchanged cisplatin (CDDP) related to nephrotoxicity were evaluated in rats in vivo using a pharmacodynamic model. Methods: CDDP was administered according to various dosing schedules (single bolus, intermittent bolus, or continuous infusion). Unchanged CDDP in plasma and urine was quantified using high-performance liquid chromatography (HPLC). The pharmacokinetics were assessed by model-independent methods. The relationship between pharmacokinetics and BUN levels was evaluated using a sigmoid maximum response (E_max) model. Results: Unchanged CDDP showed linear pharmacokinetics after single bolus injections of 1 to 5 mg/kg CDDP. Nephrotoxicity was ameliorated following intermittent bolus injection (1 mg/kg per day for 5 days) and continuous infusions (over 2 and 3 h) of the same CDDP doses (5 mg/kg), although these dosing schedules did not change the area under the concentration-time curve (AUC), total clearance (Clt), urinary excretion of unchanged CDDP or kidney platinum levels significantly. The maximum BUN level, as a nephrotoxicity marker, showed dose-related increases after single bolus injection of 1 to 5 mg/kg CDDP and after 3-h infusion of 5 to 25 mg/kg. The pharmacodynamic relationship between the maximum BUN level and C_max and between the maximum BUN level and AUC were apparently different between single bolus injection and 3-h infusion. The maximum BUN level was related to the AUC calculated by plasma concentrations of unchanged CDDP greater than the threshold level (AUC_>Cmin), a relationship most successfully described by the signoid E_max model, regardless of CDDP dose and schedule. The plasma threshold level of unchanged CDDP was determined as 0.9 μgPt/ml in rats. Conclusions: The present results substantiated the importance of C×T (AUC) value as an indicator of CDDP-induced nephrotoxicity in vivo as well as of tumor cell-killing effect of CDDP in vitro. The AUC_>Cmin of unchanged CDDP was found to be an important pharmacokinetic parameter predicting CDDP nephrotoxicity. Received: 12 February 1996 / Accepted: 5 September 1996