The value of oral cytarabine ocfosfate and etoposide in the treatment of refractory and elderly AML patients.

Twenty-one acute myeloid leukemia (AML) patients were enrolled and received oral induction therapy with cytarabine ocfosfate (SPAC) and etoposide (EP). The median age was 69 years (range: 33-86). There were 11 patients with de novo AML and 10 AML cases that had evolved from myelodysplastic syndromes. Seventeen patients had abnormal karyotypes including eight complex abnormalities, various complications, and 7 of 21 had a poor performance status (PS) with Eastern Cooperative Oncology Group (ECOG) scores of 3-4. All patients completed induction therapy without severe adverse events. Seven achieved complete remission (CR), and two achieved partial remission (PR). Uni- and multivariate analyses demonstrated a positive and significant correlation between the results of therapy (CR +/- PR) and overall survival. The plasma concentrations of cytosine arabinoside (ara-C) in some cases were higher than those previously reported, indicating the accumulation of ara-C with increasing numbers of days of SPAC administration. We conclude that this therapy is well tolerated and useful for refractory and elderly AML patients.

Complete hematologic and cytogenetic response to 2-amino-9-beta-D-arabinosyl-6-methoxy-9H-guanine in a patient with chronic myelogenous leukemia in T-cell blastic phase: a case report and review of the literature.

BACKGROUND: T-cell lymphoid blastic phase (BP) transformation is rare in chronic myelogenous leukemia (CML). 2-amino-9-beta-D-arabinosyl-6-methoxy-9H-guanine (GW506U78), a prodrug of arabinosylguanine (ara-G), is effective in T-cell leukemias. METHODS: The authors present a case of a 48-year-old male with Philadelphia chromosome (Ph) positive CML and T-cell lymphoid BP after 17 months in the chronic phase. RESULTS: Plasma pharmacokinetic studies after an infusion of GW506U78 at a dose of 40 mg/kg showed GW506U78 concentrations of 60 microM, and a peak ara-G concentration of 260 microM in the plasma. Cellular ara-G triphosphate (ara-GTP) concentration in the peripheral blood T-lymphoblasts was 80 microM at the end of GW506U78 infusion and reached a maximum of 150 microM. The patient achieved a complete response that lasted 13 months. Severe neurotoxicity related to GW506U78 was observed. CONCLUSIONS: GW506U78 showed antileukemic activity against Ph positive T-cell BP CML. Neurotoxicity was dose-limiting in this patient. Treatment with GW506U78 and modulation of ara-GTP concentrations are therapeutic strategies that require further exploration in T-cell malignancies. Investigation of other dosing schedules may limit neurotoxicity.

Pharmacological and biochemical strategies to increase the accumulation of arabinofuranosylguanine triphosphatein primary human leukemia cells.

Purine nucleoside phosphorylase deficiency leads to a dGTP-mediated T-lymphopenia, suggesting that an analogue of deoxyguanosine would be selectively effective in T-cell disease. 9-beta-D-Arabinofuranosylguanine (ara-G) is relatively resistant to hydrolysis by purine nucleoside phosphorylase and selectively toxic to T cells, but its low solubility has prevented its use in the clinic. 2-Amino-6-methoxy-arabinofuranosylpurine (GW506U) serves as the water-soluble prodrug for ara-G. A Phase I trial in patients with refractory hematological malignancies demonstrated that the clinical responses to this agent were directly related to the peak levels of ara-G 5'-triphosphate (ara-GTP) in target cells. The aim of the present study was to develop and test strategies to increase intracellular accumulation of ara-GTP in primary human leukemia cells of myeloid and B-lymphoid origin. Three strategies were tested. First, incubations with 100 microM ara-G for 4 h produced a linear median accumulation rate of 19 microM/h (range, 2-45 microM/h; n = 15) in lymphoid leukemia cells and 16 microM/h (range, 0.5-41 microM/h; n = 11) in myeloid leukemia cells. Saturation of ara-GTP accumulation was achieved only after 6-8 h exposure in both lymphoid and myeloid leukemia cells, suggesting a rationale for prolonged infusion. Second, a dose-dependent increase in ara-GTP accumulation was observed with incubations of 10-300 microM ara-G for 3 h. Hence, dosing regimens that achieve high plasma levels of ara-G during therapy may increase cellular levels of ara-GTP. Finally, a biochemical modulation approach using in vitro incubation of leukemia cells with 10 microM 9-beta-D-arabinofuranosyl-2-fluoroadenine for 3 h, followed by either 50 or 100 microM ara-G for 4 h, resulted in a statistically significant median 1.3-fold (range, 1.1-9.0-fold; P = 0.034) and 1. 8-fold (range, 0.9-10.6 fold; P = 0.018) increase in ara-GTP compared to cells incubated with ara-G alone. Extension of these studies to ex vivo incubations confirmed our in vitro findings. These strategies will be used in the design of clinical protocols to increase ara-GTP accumulation in leukemia cells during therapy.

Highly sensitive high-performance liquid chromatographic assay for 1-beta-D-arabinofuranosylcytosine-5'-stearyl phosphate (cytarabine-ocfosfate).

An ion-pair HPLC method for the determination of 1-beta-D-arabinofuranosylcytosine-5'-stearyl phosphate (cytarabine-ocfosfate I) was developed, using a phenyl-bonded column under reversed-phase conditions with a mobile phase of acetonitrile-buffered water (pH 6.8) (50:50) for isocratic elution. A reproducible sample clean-up was achieved by solid-phase extraction. In order to reach the low limit of detection of 2 ng/ml, an enrichment switching system was used. The present validation leads to a limit of quantification of 5 ng/ml with a coefficient of variation (C.V.) of 10%. The total time of measurement was shortened by a back-flush procedure to restore the conditions after each run. UV detection at 275 nm was applied. The recoveries for plasma samples ranged from 56.4 to 64.1%, regardless of drug concentrations. The intra-assay C.V. was about 4% (40 measurements at four different concentrations). The inter-assay recovery (ten measurements over ten days) at a plasma concentration of 50 ng/ml was 57% with a C.V. of 8.25%. Based on this HPLC method, the pharmacokinetics of I were measured during a clinical phase I/II study.

Relationship of 1-beta-D-arabinofuranosylcytosine in plasma to 1-beta-D-arabinofuranosylcytosine 5'-triphosphate levels in leukemic cells during treatment with high-dose 1-beta-D-arabinofuranosylcytosine.

The pharmacokinetic values of 1-beta-D-arabinofuranosylcytosine (ara-C) in plasma and its active metabolite 1-beta-D-arabinofuranosylcytosine 5'-triphosphate (ara-CTP) in circulating blast cells were studied in 11 patients with acute leukemia. ara-C was administered as a 2-h infusion (3 g/m2) followed in 12 to 24 h by a continuous infusion for 4 days in 10 patients and for 7 days in one. A steady-state concentration of ara-C in plasma (94 +/- 32 microM) was reached by the end of the 2-h infusion. Its elimination was biphasic with an initial and terminal t1/2 of 0.44 +/- 0.10 h and 2.8 +/- 0.9 h, respectively. The accumulation of ara-CTP in leukemic cells was linear and continued for up to 2 h after the bolus infusion. ara-CTP elimination was monophasic with a median t1/2 of 3.4 h (range, 1.25 to 18.9 h). The disposition of ara-C and 1-beta-D-arabinofuranosyluracil during continuous infusion was linear with dose rate over the dose range of 70 to 3000 mg/m2/day. The area under the concentration versus time curve for ara-CTP in leukemic cells was not related to the dose infused, but rather appeared to be intrinsic to the cells of each individual. As a general finding, the pharmacokinetic values of ara-CTP in circulating blasts were more heterogeneous than those of ara-C in plasma. There were marked differences in the absolute concentrations of ara-C in plasma and ara-CTP in leukemic cells at different times after the bolus infusion and also during continuous infusion. No correlation was evident between the determinants of ara-C pharmacokinetic values and those of ara-CTP. Thus, it is concluded that the pharmacokinetics of ara-C in plasma cannot predict for the metabolism of ara-CTP in leukemic cells.

Pharmacologically directed ara-C therapy for refractory leukemia.

During a two-year experience treating patients with refractory acute leukemia with a fixed 12-hour schedule of high-dose ara-C, cellular ara-CTP pharmacodynamics were ascertained in circulating blasts of these patients. A strong correlation was found between achievement of complete remission and cellular ara-CTP levels. We therefore, attempted to improve the complete remission rate in patients with low ara-CTP levels by decreasing the intermittent ara-C dosing interval, thereby raising the minimum ara-CTP level in leukemic cells between doses. This initial attempt at pharmacologic direction of chemotherapy was successful in elevating minimum ara-CTP levels but did not produce an increase in response rate, probably because the total duration of ara-CTP exposure was decreased when the dose intervals were shortened. Currently we are engaged in a new approach based on the knowledge accumulated over the past three years. Patients receive a test ara-C dose from which data on ara-CTP cellular metabolism is derived, followed by a CI of ara-C at a dose calculated individually for each patient. Preliminary results of this approach thus far indicate an increased response rate and a different spectrum of toxicity than that observed with intermittent dose ara-C. Further clinical trials will determine the true effectiveness of this approach.

Effect of liver disease on pharmacokinetics and toxicity of 9-beta-D-arabinofuranosyladenine-5-phosphate.

Plasma levels of 9-beta-D-arabinofuranosyladenine-5'-phosphate (ara-AMP) and its metabolites 9-beta-D-arabinofuranosyladenine (ara-A and 9-beta-D-arabinofuranosylhypoxanthine (ara-Hx) were determined by high-performance liquid chromatography in four patients with chronic active hepatitis positive for hepatitis B surface antigen and eight patients with severe herpesvirus infections and normal liver function. Ara-AMP was given intravenously over a 30-min period in doses ranging from 10 to 30 mg of ara-A equivalent/kg per day. The metabolism of ara-AMP did not differ significantly between the two patient groups. Ara-AMP was quickly converted to ara-A, which was rapidly deaminated to ara-Hx. The mean half-lives of ara-AMP, ara-A, and ara-Hx were 0.14 hr, 0.17 hr, and 3.5 hr, respectively. Thus, ara-AMP is rapidly metabolized and does not act as a depot form of ara-A. Patients with chronic active hepatitis demonstrated increased bone marrow sensitivity to ara-AMP and a musculoskeletal pain syndrome not observed in patients treated for herpesvirus infections.