UMLS:C0023418 - FACTA Search

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Query: UMLS:C0023418 (leukemia)
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The blast cells of acute myeloblastic leukemia (AML) usually require growth factors for optimum proliferation in cell culture. Growth factors also affect the sensitivity of AML blast cells to cytosine arabinoside (ara-C). Others have reported that factor-treated cells are more ara-C sensitive than blasts in culture without factors. These authors have reported previously that AML blasts grown with rG-CSF, with or without GM-CSF, are more sensitive than cells in GM-CSF alone. This paper reports experiments which show that changes in the ara-C sensitivities of blast cells in different growth factors are not explained by changes in the percentage of cells in the DNA synthesis (S) phase of the cycle. Blasts freshly obtained from five AML patients were cultured in either rG-CSF, rGM-CSF, or rIL-3; they were then exposed to 20 min pulses of either high specific activity tritiated thymidine (3HTdR) or a high concentration of ara-C. Regardless of the factor present, the pulse of 3HTdR decreased the number of clonogenic cells by about 50%, the result expected for actively proliferating cells with an S phase occupying about half the cycle time. The same result was found for four of the five blast cell populations grown in G-CSF and pulsed with ara-C; in contrast, clonogenic cells grown in GM-CSF or IL-3 from these four populations were not killed by ara-C. The blasts from the fifth patient were ara-C resistant under all conditions. It was concluded that exposure to GM-CSF or IL-3 decreased ara-C sensitivity in blasts that were actively making DNA. The observation was explored in more detail using a cell line (OCI/AML-1a) that is both ara-C sensitive and growth factor dependent. These studies showed that about 15 h of growth in factor are required for a change in ara-C sensitivity.
Leukemia 1991 Sep
PMID:Granulocyte-macrophage colony-stimulating factor and interleukin-3 protect leukemic blast cells from ara-C toxicity. 171 8

The effect of dipyridamole (DP) on the cellular retention of 1-beta-D-arabinofuranosylcytosine (ara-C) and its metabolites was examined in leukemic blasts that had been isolated directly from bone marrow aspirates from patients afflicted with acute myeloid leukemia (AML). When AML cells were loaded for 2 h with 1 microM [3H]-ara-C and then transferred to ara-C-free medium, total intracellular concentrations of radiolabel and [3H]-ara-C 5'-triphosphate [3H]-ara-C-CTP rapidly declined. After 8 h, total intracellular levels of tritium were 4.4 times higher if 10 microM was included in the washout medium; however, the majority of this intracellular radiolabel corresponded to [3H]-uridine arabinoside ([3H]-ara-U) and [3H]-ara-C. DP significantly increased the mean t1/2 for [3H]-ara-CTP from 102 to 136 min (P less than 0.01), but this effect was much less pronounced than that obtained for total tritium and the increase was quite variable (0-70%; median, 19%). The presence of DP in the washout medium also increased the incorporation of ara-C into DNA and the formation of ara-CDP-choline. The level of ara-CDP-choline continued to increase in both DP-containing and DP-free media for the first 4 h following drug removal and the formation of ara-CDP-choline continued during the first few hours in ara-C-free medium. At the end of the 8-h wash in DP-containing medium, the cellular concentration of ara-CDP-choline was equivalent to that found at the beginning of the washout period. Although statistically significant, the effect of DP on ara-CTP retention in AML blasts was much less pronounced than that previously observed in L5178Y leukemia. The former cells exhibited only 10% as many nucleoside transport carriers as did the L5178Y cells as measured by their capacity to bind [3H]-nitrobenzylmercaptopurine riboside (NBMPR). The effect of DP in prolonging ara-CTP retention was proportional to the number of [3H]-NBMPR binding sites. This suggests that in patients cells that exhibit extremely low transport capacity, most of the net catabolism occurs via deamination, and further inhibition of transport by DP in an effort to improve cellular retention of ara-C has little effect on ara-CTP catabolism.
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PMID:Modulation of the cellular pharmacokinetics of ara-CTP in human leukemic blasts by dipyridamole. 173 57

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 microM, 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 microM, the CSF steady-state concentration was 8.3 +/- 1.1 microM, and the CSF: plasma ratio was 0.62 +/- 0.14. The plasma elimination 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.
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PMID:Plasma and cerebrospinal fluid pharmacokinetics of cytosine arabinoside in dogs. 174 43

A 64-year-old man was admitted to our hospital with leukopenia. On admission, leukocyte count in the peripheral blood was 1,600/microliters, containing 24.5% blasts of lymphoid appearance, which were negative for myeloperoxidase. A bone marrow aspiration showed hypoplasia with increased blasts (31.6%). The blasts were ultrastructurally positive for platelet peroxidase (PPO) and positive for platelet membrane glycoprotein IIb/IIIa complex. A diagnosis of acute megakaryoblastic leukemia was made. Chemotherapy with behenoyl-ara C (BH-AC) (150 mg/day) was transiently effective. However, after three months, numerous nodules without itching appeared over the entire body, particularly on the anterior chest. A biopsy of the skin lesion revealed a diffuse fibrosis with infiltrations of the blasts. Bone marrow aspirations were dry tap, and a bone marrow biopsy showed marked myelofibrosis. Then, severe headache, vomiting, and loss of consciousness developed, and a lumbar puncture revealed infiltrations of blasts. Although methotrexate was intrathecally injected, he died due to the respiratory failure. As far as we know, a case of acute megakaryoblastic leukemia with leukemia cutis and meningeal leukemia is quite rare. In addition, it is interesting that megakaryoblastic leukemia was accompanied with both the fibrosis of skin and the myelofibrosis.
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PMID:[Acute megakaryoblastic leukemia with leukemia cutis, meningeal leukemia, and myelofibrosis]. 175 56

Bone marrow leukemia cells from eight adults with untreated acute myeloid leukemia (AML) were evaluated before and after three daily leukaphereses to determine if mechanical cytoreduction can modulate the cell cycle distribution. The percentage of cells in S-phase and the proliferative fraction (PF = %S + %G2M) were determined by flow cytometry after dual labeling with bromodeoxyuridine and propidium iodide. Prior to pheresis the median %S and PF were 5.4 and 15.4%, respectively. The median change in %S was +2.5% (range -5.5 to +18.8) with increases greater than or equal to 3.7% in 4/8 patients. The median change in PF was +6.1% (range -13.8 to +25.3) with an increase of greater than or equal to 3.6% in 6/8 patients. The median absolute changes of 2.5 and 6.1% represent increases of 47% for %S and 40% for PF compared to the day 1 (pre-pheresis) median values. As the number of nucleoside transporters in the cell membrane [nitrobenzylmercaptopurine riboside (NBMPR) binding sites] has been related to the percentage of cells in S-phase and to cytosine arabinoside (ara-C) cellular pharmacology, these were also measured before and after leukapheresis. Changes in the number of NBMPR binding sites varied widely with a median increase of 365 sites per cell (range -26,061 to +10,396). The change in NBMPR sites was significantly and positively correlated with changes in %S (r = 0.829, p = 0.042). These data suggest that mechanical cytoreduction by leukapheresis can increase the fraction of leukemia cells in S-phase and the PF in some patients with AML. The increase in %S is accompanied by an increase in NBMPR binding sites per cell. These changes in leukemia cell characteristics would be expected to result in an increase in efficacy of ara-C or other S-phase specific agents.
Leukemia 1991 Dec
PMID:Leukapheresis induced changes in cell cycle distribution and nucleoside transporters in patients with untreated acute myeloid leukemia. 177 52

In summary, there are compelling laboratory and clinical data indicating that higher doses of ara-C than are currently used in SDaC protocols constitute optimal therapy. The cellular pharmacokinetics of ara-C are optimized at extracellular drug concentrations in the 10 to 15 mumol/L range. At these concentrations, transport rates are no longer rate-limiting, and ara-C phosphorylation capacity is saturated. The prime determinants of ara-C effect then shift to multiple intracellular events including anabolism to nucleotides, catabolism via deamination by Cyd-dCyd deaminase and dCMP deaminase, half-life of ara-CTP, the extent of incorporation into DNA, and the half-life of ara-CMP residues in DNA. It is postulated that at these high doses an additional effect of ara-C occurs on the cell membrane through affects on membrane phospholipid synthesis. This effect may contribute to the brisk cell lysis associated with HiDaC treatment. When administered as repetitive doses of 3 g/m2 over a 1- to 3-hour period, systemic deamination of ara-C gives rise to high plasma concentrations of ara-U. This metabolite has a long plasma half-life and, at least in the mouse, is concentrated in the liver and kidneys. High concentrations in these organs retard the further catabolism of ara-C and thus increase the systemic AUC providing a longer exposure period to the drug. A similar mechanism may obtain in patients treated with HiDaC. The observed decreased clearance of ara-C when administered in gram versus milligram doses and the long-terminal gamma-phase in plasma clearance of the drug associated with HiDaC usage quite probably reflects this effect of ara-U in patients. Additionally, by some as yet unknown mechanism, high concentrations of ara-U cause accumulation of leukemia cells in S-phase, the phase of the cell cycle wherein ara-C is maximally effective. This effect of ara-U may add to the cytokinetic effects initiated by rapid cytoreduction, which summate in the observed enhancement of the proliferative fraction of residual leukemia cells on day 8. The effect of a second course of therapy at this time is thereby enhanced. These dose-related and metabolite-drug interactions that occur when ara-C is given at high doses constitute a means for "self-potentiation" and may thus contribute to its overall therapeutic efficacy.
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PMID:Effect of dose on the pharmacokinetic and pharmacodynamic effects of cytarabine. 178 Jul 54

The 1-beta-D-arabinofuranosylcytosine (ara-C) conjugates 1-O-alkyl (ether) and 1-S-alkyl (thioether) phospholipids, being analogues of ara-CDP-sn-1,2-O-dipalmitoylglycerol (1), showed significant antitumor activity against L1210 and P388 leukemia in vivo. The more active conjugates include the 1-O-alkyl analogues, ara-CDP-rac-1-O-hexadecyl-2-O-palmitoylglycerol (2) and ara-CDP-rac-1-O-octa-decyl-2-O-palmitoylglycerol (3), and the corresponding 1-S-alkyl analogues, ara-CDP-rac-1-S-hexadecyl-2-O-palmitoyl-1-thioglycerol (4) and ara-CDP-rac-1-S-octadecyl-2-O-palmitoyl-1-thioglycerol (5, Cytoros). The conjugates were formulated by sonication, in which the conjugates existed as discs (size 0.01-0.04 microns). Among the conjugates of the three different phospholipids, the 1-S-alkyl analogues 4 and 5 displayed the strongest antitumor activity against L1210 leukemia in mice, followed by the 1-O-alkyl (2 and 3) and the 1-O-acyl (1) analogues. The 1-S-alkyl analogue 5 was considerably more effective than the 1-O-acyl analogue 1 against myelomonocytic WEHI-3B leukemia in mice. Conjugate 5 (Cytoros) showed a significant therapeutic activity in mice with colon 26 carcinoma, M5076 sarcoma, and C-1300 neuroblastoma. Furthermore, this agent inhibited liver metastases of M5076 sarcoma. Conjugates 3 and 5 also inhibited the metastasis of 3-Lewis lung carcinoma to the lungs of mice. Cytoros (5) and its analogues, with other ether and thioether phospholipids, appear to offer increased therapeutic benefit to mice with tumors.
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PMID:1-beta-D-arabinofuranosylcytosine conjugates of ether and thioether phospholipids. A new class of ara-C prodrug with improved antitumor activity. 181 47

The treatment of patients with relapsed or refractory acute myeloid leukemia (AML) with high dose cytosine arabinoside (ara-C) results in short-lived complete response rates of 30-50%. We have previously shown that entry of myeloid leukemic cells into S phase can be accelerated in vitro through the use of recombinant human granulocyte-macrophage colony-stimulating factor (rhGM-CSF), resulting in enhancement of ara-C-mediated cytotoxicity. In order to evaluate the in vivo biological and clinical effects of this strategy in patients with high risk AML, we treated three patients with either refractory or relapsed disease with a continuous infusion of rhGM-CSF (0.45 micrograms/kg/h aglycoprotein) for 18 h, followed by the institution of high dose ara-C and continuation of rhGM-CSF throughout the 4 day duration of ara-C treatment. Prior to therapy, no patient had detectable levels of circulating rhGM-CSF, and there was no evidence of GM-CSF receptor occupancy in leukemic myeloblasts. After 18 h of rhGM-CSF therapy, all patients had biologically active levels of circulating rhGM-CSF (7.9-12.0 ng/ml), and two patients showed a significant degree of leukemic GM-CSF receptor occupancy without evidence of GM-CSF receptor down-regulation. A significant rise in the S phase fraction of leukemic myeloblasts was observed at 18 h of rhGM-CSF treatment in all three patients (29-56% increment). The toxicity of combined rhGM-CSF/ara-C therapy included pericarditis and cerebellar degeneration in one patient, fever and mild renal dysfunction in two patients, and mild hepatic dysfunction in all three patients. Each patient showed a transient rise in the absolute neutrophil and blast count during rhGM-CSF/ara-C administration, followed by profound, but clinically tolerable, myelosuppression. No patient developed clinical evidence of leukostasis. There was one death related to pericardial tamponade, one death related to refractory disease, and one clinical and cytogenetic remission. These results suggest that exogenously administered rhGM-CSF is capable of rapidly mobilizing leukemic cells into S phase in vivo and theoretically should be useful in overcoming kinetic resistance to ara-C. Clinical trials of this regimen in patients with high risk AML who are not already pharmacologically resistant to ara-C are warranted.
Leukemia 1991 Mar
PMID:Simultaneous administration of granulocyte-macrophage colony-stimulating factor and cytosine arabinoside for the treatment of relapsed acute myeloid leukemia. 182 36

We examined the plasma and cerebrospinal fluid (CSF) pharmacokinetics of 1-beta-D-arabinofuranosylcytosine (ara-C) and 1-beta-D-arabinofuranosyluracil (ara-U) in 19 patients with acute leukemia in order to determine whether ara-C or ara-U accumulate in these fluid compartments over time. Plasma and CSF samples were obtained just prior to the conclusion of the first and seventh, and immediately before the second and eighth, 2-h, twice-daily i.v. infusions of 3 g/m2/dose of ara-C (n = 10), 2 g/m2/dose of ara-C (n = 3), and 0.75 g/m2/dose of ara-C (n = 6). There was no accumulation of ara-C in the plasma or CSF, or of ara-U in the plasma following repeated ara-C infusions, ara-U did accumulate in the CSF; the end-dose 1/end-dose 7 CSF ara-U ratio was 0.35 +/- 0.12 and significantly different from this ratio for CSF ara-C (2.10 +/- 3.01; P = 0.004). The end-dose 7 CSF ara-U level was greater than the end-dose 1 CSF ara-U level in all paired specimens. There was a significant correlation between the dose of ara-C administered and the end-dose plasma ara-C and the end-dose CSF ara-U levels (P less than 0.02). One patient who received 3 g/m2/dose of ara-C developed neurotoxicity; his plasma and CSF ara-C and ara-U levels were not extraordinary during the period of ara-C administration, but he had persistent CSF ara-U demonstrable 75 h after his final ara-C dose. CSF ara-U accumulation might underlie the pathophysiology of ara-C-induced neurotoxicity. Intermediate doses of ara-C given i.v. (0.75 g/m2/dose over 2 h) appeared to generate therapeutic CSF ara-C levels and cleared CSF leukemia in one patient.
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PMID:Plasma and cerebrospinal fluid pharmacokinetics of 1-beta-D-arabinofuranosylcytosine and 1-beta-D-arabinofuranosyluracil following the repeated intravenous administration of high- and intermediate-dose 1-beta-D-arabinofuranosylcytosine. 186 35

The sensitivity of human myelogenous leukemia cells to 1-beta-D-arabinofuranosylcytosine (ara-C) during induction of differentiation was examined. Treatment with hemin greatly increased the sensitivity of erythroid leukemia cells to ara-C. The enhancement of ara-C sensitivity by hemin was not as remarkable in nonerythroid leukemia cells. Hemin altered the metabolism of ara-C in human erythroleukemia K562 cells by reducing ara-C deaminase activity, increasing intracellular accumulation of ara-C, and activating the nucleoside kinases. These alterations may be involved in the enhancing effect of hemin on sensitivity of ara-C. These results suggest that some inducers of differentiation potentiate the antileukemic effect of ara-C on human erythroleukemia cells.
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PMID:Hemin enhances the sensitivity of erythroleukemia cells to 1-beta-D-arabinofuranosylcytosine by both activation of deoxycytidine kinase and reduction of cytidine deaminase activity. 187 97

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