Collection of peripheral blood stem cells following administration of paclitaxel, cyclophosphamide, and filgrastim in patients with breast and ovarian cancer.

PURPOSE: To determine the toxicities and efficacy of paclitaxel, cyclophosphamide (Cy), and recombinant human granulocyte-colony stimulating factor (filgrastim) administered for mobilization and collection of peripheral blood stem cells (PBSC) in patients with breast and ovarian cancer. METHODS: One hundred and forty-one patients with breast (n = 115) or ovarian cancer (n = 26) received paclitaxel 170 mg/m2 and Cy 2 gm/m2 (n = 42) or paclitaxel 200 mg/m2, Cy 3 gm/m2 (n = 99), and filgrastim (6 micrograms/kg/day) followed by collection of PBSC by apheresis. RESULTS: The 2 dose levels of paclitaxel and Cy tested were well tolerated. The median yield of CD34+ cells from all patients was 6.53 x 10(6)/kg (range, 0.11-51.76) collected with a median of 2 aphereses (range, 1-8). The target dose of 2.5 x 10(6) CD34+ cells/kg was achieved in 85% of patients. The mean daily collection of CD34+ cells was 5.46 x 10(6)/kg for patients receiving 200 mg/m2 of paclitaxel and 3 gm/m2 of Cy as compared to 2.77 for patients receiving the lower doses (p = 0.0005). Increasing the dose of paclitaxel and Cy did not significantly increase the fraction of patients achieving a target dose of 2.5 x 10(6) CD34+ cells/kg (87% vs 81%, p = 0.367) but did increase the fraction achieving a target of 5.0 x 10(6) CD34+ cells/kg (73% vs 45%, p = 0.002). The mean daily collection of CD34+ cells for patients who had received only 1 prior chemotherapy regimen was 6.59 x 10(6)/kg as compared to 3.47 for patients who had received more than 1 prior chemotherapy regimen (p < 0.0001). Prior radiation therapy (p = 0.003) and patient performance status (p = 0.047) were adverse risk factors for achieving a target dose of > or = 2.5 x 10(6) CD34+ cells/kg. CONCLUSIONS: The combination of paclitaxel, Cy, and filgrastim can be administered with acceptable toxicity, allowing collection of adequate quantities of PBSC from the majority of patients with breast and ovarian cancer. Increasing the doses of paclitaxel and Cy increased the number of CD34+ cells collected and decreased the number of apheresis procedures necessary to collect target cell doses. However, increasing drug doses did not increase the fraction of patients yielding the minimum CD34+ target dose of 2.5 x 10(6)/kg. Collection of PBSC early in the disease course is the best strategy to assure optimal CD34+ cell doses in all patients.

Phase I clinical and pharmacological study of liposome-entrapped cis-bis-neodecanoato-trans-R,R-1,2-diaminocyclohexane platinum(II).

cis-Bis-neodecanoato-trans-R,R-1,2-diaminocyclohexaneplatinum++ +(II) (NDDP) is a liposome dependent cisplatin analogue since the liposome carrier is required for its i.v. administration and for its biological activity. A Phase I study of liposome entrapped NDDP (L-NDDP) was performed using a single i.v. injection every 4 weeks. L-NDDP was prepared and characterized at M. D. Anderson Cancer Center. The maximum tolerated dose of L-NDDP was 312.5 mg/m2. The dose-limiting toxicity was myelosuppression, affecting all three blood cell lineages. The granulocyte nadir occurred on days 14-18, and the platelet nadir consistently earlier (days 11-12). The median day of recovery of blood cell counts was day 21 (range, 18-32). Other toxicities included grade 2 nausea and vomiting, fever consisting of a single temperature spike in most patients, grade 1 diarrhea after 60% of courses, and grade 1-2 malaise lasting for 5-10 days after the infusion in 73% of courses. Transient alanine aminotransferase elevations without clinical relevance were common. No signs of renal dysfunction or ototoxicity were observed. One patient with a preexisting peripheral neuropathy showed some progression of the neuropathy after a cumulative dose of 1605 mg/m2. Except for fever and transient liver dysfunction, no liposome related side effects were observed in spite of the high doses of lipid administered. The blood clearance of L-NDDP fits a two-compartment model at lower doses and a single-compartment model at the maximum tolerated dose, suggesting that saturation of the reticuloendothelial organs occurs at the maximum tolerated dose. Two minimal responses were observed. L-NDDP has a toxicity profile similar to that of carboplatin. Phase II studies to address the issue of how the therapeutic index of platinum compounds is affected by liposome entrapment are being planned.

Single-dose cyclosporine pharmacokinetics in various biological fluids of patients receiving allogeneic marrow transplantation.

The clinical usefulness of cyclosporine is hampered by dose-limiting toxicities to the kidney that are not predicted by drug levels in serum or whole blood. Because of its lipophilic nature, circulating plasma lipoproteins may play a role in drug disposition. This study characterized the pharmacokinetic parameters of a single 2-mg/kg i.v. infusion of cyclosporine in the whole blood, plasma, high-density (HDL), low-density (LDL), and very low-density (VLDL) lipoprotein fractions of nine patients before bone marrow transplantation. The dose- and protein-corrected area under the concentration-time curve in whole blood; plasma; and HDL, LDL, and VLDL compartments were 44.6 +/- 11.3, 19.2 +/- 2.4; 33.6 +/- 12.3, 49.0 +/- 19.9, and 17.5 +/- 9.0 ng h/ml, respectively. The mean half-life of the drug from the VLDL fraction was significantly less than from the other biologic fluids. The systemic clearance rate of cyclosporine was greater in the total plasma or VLDL fractions compared with whole blood and the HDL and LDL fractions. The HDL-cyclosporine clearance inversely correlated with the serum creatinine (r = -0.71; p less than 0.05) and total bilirubin levels (r = -0.76; p less than 0.05). The plasma half-life and volume of distribution directly correlated with fasting HDL cholesterol levels (r = 0.94 and 0.99; p less than 0.01). Correlations between pharmacokinetic parameters and lipid fractions suggest a role of lipids in the distribution of cyclosporine. These data may be useful in the development of guidelines for therapeutic drug monitoring of cyclosporine in the transplantation population.

Increased sensitivity in a radioimmunoassay for measuring cyclosporine in lipoprotein fractions.

We describe a modification of the commercially available cyclosporine (CAS) 3H-RIA kit, allowing detection of drug in lipoprotein fractions obtained by ultracentrifugation. Sodium bromide solutions containing the lipoprotein fractions were dried and reconstituted with drug-free plasma. Methanolic extractions were centrifuged, and 250 microL of the supernate was dried and reconstituted with 50 microL of methanol. Buffer, radioactive tracer, and monoclonal antibody were then added and incubated for 2 h at 4 degrees C. Samples were subjected to charcoal de-activation and then centrifuged, and the radioactivity in the supernate was counted. The limit of detection of CSA was 2.5 micrograms/L; analytical recovery was between 97.5% and 101.3%. Within- and between-day CVs were less than 9%. We conclude that the present method may be beneficial for therapeutic drug monitoring of CSA in lipoprotein fractions.

Preclinical toxicity and pharmacology of liposome-entrapped cis-bis-neodecanoato-trans-R,R-1,2-diaminocyclohexane platinum(II).

Liposome-entrapped cis-bis-neodecanoate-trans-R,R-1,2-diaminocylohexane platinum(II) (L-NDDP) is a new lipophilic cisplatin derivative formulated in a liposomal carrier currently in phase I clinical trials. The preclinical toxicity and pharmacology of L-NDDP were studied in mice and dogs. At the LD50 dose (i.v. bolus) in mice (60.5 mg/kg or 181.5 mg/m2), a tenfold decrease in the granulocyte and platelet counts was observed in the absence of renal toxic effects. In dogs, the maximum tolerated dose (MTD) of L-NDDP given i.v. over a period of 45-60 min was 150 mg/m2. This dose produced significant vomiting (6-18 episodes), minimal renal dysfunction, a maximal decrease in granulocyte and platelet counts of from 30% to 70%, and acute and transient elevation of liver enzymes. Higher doses (225 and 300 mg/m2) resulted in severe gastrointestinal (GI) toxicity in one animal and the death of two others within 48 h. Autopsy results showed multifocal hemorrhages in the lungs, GI tract, kidney, and liver. Three dogs were treated monthly with the MTD up to a cumulative dose of 637.5-712.5 mg/m2 with excellent tolerance. No cumulative myelosuppression or liver dysfunction was observed, whereas a slight increase in the creatinine baseline level was detected in all three animals. Autopsy results at the end of the study showed mild changes limited to the liver, kidney, and GI tract. Pharmacologic studies showed that the drug was cleared, fitting a two-compartment model with a mean t1/2 alpha of 7.1 min and a t1/2 beta of 87.8 h. These studies show that L-NDDP can safely be given at therapeutic doses to animals and that the dose-limiting toxic effects consists of myelosuppression in mice and a multiorgan hemorrhagic syndrome related to vascular injury in dogs.

Cellular pharmacology of liposomal cis-bis-neodecanoato-trans-R,R-1,2-diaminocyclohexaneplatinum (II) in mouse resident peritoneal macrophages, Kupffer cells, and hepatocytes.

The in vitro and in vivo interaction of liposomal cis-bis-neodecanoato-trans-R,R-1,2-diaminocyclohexaneplatinum++ + (II) (L-NDDP) with mouse resident peritoneal macrophages (RPM), Kupffer cells (KC), and hepatocytes was studied. The peak in vitro uptake of L-NDDP by RPM was 12.5 ng elemental platinum/100 micrograms cell protein and constituted 0.2% of the platinum available for phagocytosis. The subsequent release of platinum by RPM was rapid initially, with a 20-fold increase over the first 4 h, followed by a plateau; ultrafilterable (free) platinum constituted 50% of the total platinum released at 24 h. The retained intracellular platinum in RPM at 24 h was close to 50% of that initially present. The peak in vitro uptake of L-NDDP by KC was 11.3 ng platinum/100 micrograms cell protein and amounted to 0.2% of the platinum available for phagocytosis. The release of platinum by KC was detectable only after 4 h of incubation and increased 3-fold over the next 14 h. The ultrafilterable platinum released by KC at 18 h was 40% of the total platinum released. The retained intracellular platinum in KC at 18 h was 33% of that initially present. The peak in vitro uptake of L-NDDP by hepatocytes was almost 50 ng platinum/100 micrograms cell protein and constituted 0.8% of the platinum available for intake. Following the i.v. injection of L-NDDP, hepatocytes contained up to 6-fold higher platinum concentrations than KC. This observation was supported by transmission electron microscopy showing a higher concentration of multilamellar vesicles within hepatocytes than in KC, 5 min after i.v. injection of L-NDDP. These findings suggest that L-NDDP becomes available to the liver following i.v. injection, that both macrophages and hepatocytes play a role in the metabolism of L-NDDP, and that Kupffer cells could mediate a sustained release of platinum in the liver following the interaction with L-NDDP, indicating the potential of L-NDDP for the treatment of tumors in the liver.

Ultrastructural and freeze fracture localization of multilamellar liposomes containing a lipophilic cisplatin analogue in normal tissues and liver metastases of M5076 reticulosarcoma.

The tissue localization of multilamellar vesicles (MLV) (size 0.5-5.0 microns) composed of dimyristoylphosphatidyl choline (DMPC) and dimyristoylphosphatidyl glycerol (DMPG) (molar ratio 7:3) containing a lipophilic cisplatin analogue (NDDP) was studied in mice by freeze fracture (FF) and transmission electron microscopy (TEM). Liposomes were observed within cytoplasmic vacuoles of hepatocytes and Kupffer cells in normal mice as early as 5 minutes after intravenous (iv) administration of MLV-NDDP. Liposomes within hepatocytes were more numerous but smaller in diameter (0.5-2.0 microns) than those within Kupffer cells (2.0-4.0 microns). In normal lung examined by FF or TEM at 5 minutes after MLV-NDDP administration, liposomes were only observed in the intravascular space. Liposomes could not be identified within Type I or II pneumocytes nor within the alveolar space. Two hours after iv administration, the distribution within the liver showed an increased number of liposomes in the hepatocytes with some evidence of liposome decomposition. The distribution in the lung was virtually identical to that observed at 5 minutes. The pattern of tissue localization within lung and liver of empty MLV 5 minutes and 2 hours after iv administration was identical to that of MLV-NDDP. In mice bearing gross liver metastases of M5076 reticulosarcoma, liposomes were present in the cytoplasm of tumor cells as well as normal cells 5 minutes and 2 hours after the iv administration of MLV-NDDP. These studies suggest that MLV composed of DMPC and DMPG containing NDDP are able to cross the liver sinusoidal capillaries and gain access to both hepatocytes from normal liver and malignant cells of M5076 reticulosarcoma from liver metastases.

Pharmacokinetics and tissue distribution of liposome-encapsulated cis-bis-N-decyl-iminodiacetato-1,2-diaminocyclohexane-platinum (II).

The pharmacokinetics and tissue distribution of a lipophilic analogue of cisplatin, cis-bis-N-decyl-iminodiacetato-1,2-diaminocyclohexane platinum (II) (N-decyl-IDP), were studied after the i.v. administration of the free drug in suspension in phosphate-buffered saline (F-N-decyl-IDP) and encapsulated in multilamellar liposomes comprising dimyristoyl phosphatidylcholine and dimyristoyl phosphatidylglycerol at a molar ratio of 7:3 (L-N-decyl-IDP). The encapsulation efficiency and stability at 14 days of L-N-decyl-IDP were greater than 95%. The blood clearance of both forms of the drug fit a two-compartment model. The peak blood level of elemental platinum for L-N-decyl-IDP was fourfold higher than for the free drug (24.2 versus 6.1 micrograms/ml). In consequence, a fourfold difference in the volumes of distribution was observed (176 ml/kg for L-N-decyl-IDP versus 608 ml/kg for F-N-decyl-IDP). Liposome encapsulation reduced the drug clearance by threefold; therefore, the CXT of L-N-decyl-IDP was threefold higher than that of F-N-decyl-IDP (1308 micrograms platinum/ml per min versus 395 micrograms platinum/ml per min). Tissue platinum levels were significantly increased by liposome encapsulation in the lung (33 versus 3.6 micrograms/g), spleen (38.3 micrograms/g versus none detected), and liver (16.2 versus 11.7 micrograms/g), and unchanged in the kidneys. Although only F-N-decyl-IDP resulted in detectable levels of platinum in the small bowel (70.5 micrograms/g), the stool excretion was similar for both forms of the drug. The organ distribution changes secondary to liposome encapsulation may result in an increased antitumor activity of N-decyl-IDP in tumors involving the lung, spleen, and liver, and avoidance of gastrointestinal toxicity.