UMLS:C0023467 - FACTA Search

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Query: UMLS:C0023467 (acute myeloid leukemia)
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WHAT IS HYPOPLASTIC ANEMIA? Aplastic anemia is a hematological disease characterized by pancytopenia and bone marrow hypoplasia. Acquired cases of aplastic anemia are almost all idiopathic and arise from unknown causes. Other cases of aplastic anemia are secondary and are caused by radiation, chemicals or viruses. PATHOPHYSIOLOGY: Aplastic anemia is manifested as a marked reduction in the number of pluripotent hematopoietic stem cells, but why this occurs is still uncertain. Some of the proposed causes include abnormalities of the hematopoietic stem cells, abnormalities in the hematopoietic microenvironment, and immunologically mediated damage to the hematopoietic stem cells (Figure 1). ABNORMALTIES OF THE HEMATOPOIETIC STEM CELLS: Patients with aplastic anemia, and long-term survivors in particular, are at increased risk of developing paroxysmal nocturnal hemoglobinuria (PNH), myelodysplastic syndrome (MDS), or acute myelocytic leukemia. This suggests that, in at least some of these patients, the hematopoietic stem cells themselves are abnormal. It also suggests that in some of these patients the blood cells are clonal (that is, all the blood cells are derived from a single pluripotent stem cell). In short, what these findings imply is that aplastic anemia may be caused by the emergence of an abnormal clone. Clonal hematopoiesis, however, can also be considered nothing more than a consequence. In other words, it is possible that hematopoiesis in this kind of patient is performed by a lone pluripotent stem cell that somehow managed to survive eradication. No definitive interpretation of clonal hematopoiesis has been agreed upon, and it is still a topic for future research. ABNORMAL HEMATOPOIETIC MICROENVIRONMENT: The presence of stromal cells, which form the microenvironment of bone marrow, is very important in hematopoiesis. Hematopoietic stem cells proliferate and differentiate either by adhering to stromal cells or by being stimulated by the various hematopoietic factors that stromal cells produce. Therefore, it is quite possible that aplastic anemia is caused by abnormalities in the hematopoietic microenvironment. However, many separate studies have demonstrated that the hematopoietic microenvironment in the vast majority of aplastic anemia cases is normal. IMMUNE MECHANISMS: Immunosuppressive agents are often effective in treating aplastic anemia, and therefore it is believed that immunological mechanisms contribute to the disease in more than half the cases. The following mechanisms have been proposed as causes for the onset of immunologically mediated aplastic anemia: * Decreases in Hematopoietic Factors Produced by Monocytes and Lymphocytes. Some patients with aplastic anemia show decreased production of interleukin 1 (IL-1) by peripheral blood monocytes, and it is possible that a drop in the concentration of this factor is linked to the onset of the disease [1]. It is also possible, however, that decreased IL-1 production by monocytes is not a cause of the disease, but merely a consequence. Moreover, no cases have been reported that exhibit reduced production of hematopoietic factors produced by lymphocytes such as GM-CSF, IL-3, or IL-6. * Damage by Cytokines that Suppress Hematopoiesis. It has been reported that increased levels of interferon &ggr; (IFN-&ggr;), which is produced by lymphocytes, and tumor necrosis factor &agr; (TNF-&agr;), which is produced by monocytes and macrophages, are found in the bone marrow and peripheral blood of aplastic anemia patients [2, 3]. These two factors act as suppressors of hematopoiesis, and it is possible that they contribute to the disease. The increase of these inflammatory cytokines in the bone marrow strongly suggests the presence of either specific or non-specific destruction of the hematopoietic stem cells by immunoregulatory cells. * Suppression of Hematopoiesis by Cytotoxic T Cells (Killer T Cells). Cases have been reported in which cytotoxic T cell clones that damage the autologous hematopoietic precursor cells are present [4]. Therefore, we can easily conceive of a mechanism in which these cytotoxic T cells specifically destroy the hematopoietic stem cells and cause aplastic anemia. * Suppression of Hematopoiesis by Natural Killer (NK) Cells. NK activity of aplastic anemia patients is depressed, and, generally speaking, it is highly unlikely that NK cells contribute to this condition. However, it has been reported that clonal NK cells are thought to cause the disease in patients exhibiting pancytopenia and bone marrow hypoplasia. Therefore, when this disease is diagnosed, a peripheral blood granular lymphocyte count and NK cell surface marker analysis should always be performed. DIAGNOSIS: A necessary condition for the diagnosis of aplastic anemia is the presence of pancytopenia. Moreover, it is necessary to rule out all other causes of pancytopenia. It is especially important in differential diagnosis to look for PNH and MDS. In cases of aplastic anemia there are patients that exhibit PNH during the course of the disease, and this condition is called aplastic anemia-PNH syndrome. It has recently been shown that bone marrow and peripheral blood cells in some patients diagnosed with aplastic anemia are partially lacking GPI anchor proteins (CD16, CD55, and CD59) [5]. Whether such patients become to exhibit aplastic anemia-PNH syndrome in the future remains to be elucidated. In MDS the bone marrow generally exhibits normoplasia or hyperplasia, and only in rare cases does it exhibit hypoplasia. This condition is referred to as hypoplastic MDS. Hypoplastic MDS can be differentiated from aplastic anemia by the presence of abnormal cell morphology that is sometimes accompanied by chromosomal abnormalities. TREATMENT:Aplastic anemia is treated with androgens, high-dose methylprednisolone, cyclosporin A (CyA), antithymocyte globulin (ATG), antilymphocyte globulin (ALG), hematopoietic growth factors such as G-CSF, and bone marrow transplantation. Interestingly, patients who require continuous CyA administration to maintain stable hematopoiesis have a specific HLA class II haplotype (DRB1*1501-DQA1*0102-DQB1*0602) [6]. Recent reports from EBMT SAA Working Party showed the excellent therapeutic result (response rate 82%) when severe cases were treated with ALG, CyA and G-CSF in combination [7].
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PMID:Special Education: Aplastic Anemia. 1038 86

A 49-year-old man diagnosed with hairy cell leukemia (HCL) achieved a complete remission lasting 4 years after treatment with cladrabine and subsequently developed acute myeloid leukemia. Although a wide variety of second malignancies have been noted in HCL with an incidence of 8.7%, acute myeloid leukemia (AML) has been reported only once previously in a splenectomized patient who had been treated with alpha interferon.
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PMID:Secondary acute myeloid leukemia 4 years after the diagnosis of hairy cell leukemia: case report and review of the literature. 1097 62

From March 1994 to November 1994, 16 patients with high risk hematological malignancies were entered in a phase I clinical trial, designed to confirm the toxicity of cyclosporine and gamma interferon given to induce autologous graft-versus-host disease (GVHD) after autologous bone marrow transplantation (ABMT). This trial was based on the results in a rodent model, in which cyclosporine given after ABMT induces an autoimmune syndrome (autologous GVHD) identical to allogeneic GVHD. Further, this autologous GVHD is associated with a graft-versus-tumor effect augmented by interferon that upregulates MHC class II expression on normal and tumor cells, the target of the cytolytic T cells in autologous GVHD. In this trial, cyclosporine 1 mg/kg/day was given from the day of bone marrow reinfusion until the completion of the interferon and gamma-interferon. Gamma-interferon at 0.025 mg/m2 every other day was started when the total white cell count was >200 cells/ml for 2 consecutive days and continued for a total of 10 doses after ABMT. The preparative regimens were busulfan and cyclophosphamide, or cyclophosphamide with total body irradiation. All patients received 4HC-purged marrow grafts. Median age was 45 years (range 19-68). The diagnoses included chemo-resistant non-Hodgkin's lymphoma (10), acute lymphoblastic leukemia (two), chemo-resistant Hodgkin's disease (two), acute myeloid leukemia (one), and multiple myeloma (one). Median absolute neutrophil count recovery was 25.5 days (range 19-46 days). Median platelet count recovery was 40.5 days (range 28-279 days). There were nine deaths, two were related to transplant toxicity (infection), while the other seven were due to relapse. Event-free survival with a median of 964 days (range 19-1441 days of follow-up was 44%. In conclusion, treatment with cyclosporine, and gamma-interferon after ABMT was well tolerated and did not impair engraftment. Further studies with a larger number of patients are required to document any beneficial anti-tumor effect of autologous GVHD induction after ABMT.
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PMID:Immune modulation in autologous bone marrow transplantation: cyclosporine and gamma-interferon trial. 1049 Jul 29

To increase the immunogenicity of leukemic cells, attempts were made to generate dendritic-like antigen presenting cells (DC) from AML blasts from 14 patients with AML FAB classifications M0-M5. Leukemic cells were cultured in the presence or absence of various cytokines including GM-CSF, SCF, TNF-alpha, IL-4, and gamma-interferon. After various intervals recovery of viable cells was measured and expression of CD80, CD86, CD40, CD54, CD58, and CD11a was analyzed by flow cytometry. Functionally, DC derived from six AML samples were tested in a mixed lymphocyte response (MLR) using HLA-DR mismatched donor T cells as responder cells. Proliferation (5/14) or increased survival (7/14) of AML cells was observed in the presence of GM-CSF, SCF, and TNF-alpha. Only in the AML M2, M3, and M4 FAB subtypes proliferation was found. GM-CSF, SCF, and TNF-alpha induced morphologic changes typical for DC and increased the expression of costimulatory and adhesion molecules. No significant effect of IL-4 or gamma-interferon was observed. The day of maximal expression of these molecules varied. In cases with minor upregulation of CD80 or CD86, no further stimulation using CD40-L activation was observed. In the three cases tested, the DC-like cells retained the chromosomal abnormalities present in the original AML cells. In five out of six cases tested an increase in allostimulatory capacity was found at the day of maximal expression of costimulatory and adhesion molecules. In two patients a decrease in stimulatory capacity was found at day 7 compared with day 2 correlating with a decreased expression of these molecules. In conclusion, AML cells can be induced to increase their stimulatory capacity by upregulating costimulatory and adhesion molecules.
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PMID:The generation of dendritic-like cells with increased allostimulatory function from acute myeloid leukemia cells of various FAB subclasses. 1082 85

Vasculitis may accompany neoplasias and be of paraneoplastic type or associated with drugs used in patient treatment. We evaluated skin biopsies of twenty-eight cases with vasculitis accompanying leukemias reviewed and clinical outcome was evaluated. Eleven of the 28 cases had paraneoplastic vasculitis and 17 had vasculitis associated with various drugs including chemotherapy, cytokines and antibacterial agents. Paraneoplastic vasculitis was seen in 3 cases with chronic myelocytic leukemia in blastic phase, 5 patients with acute myeloblastic leukemia, and 3 with myelodysplastic syndrome. Drugs responsible for the 17 cases of vasculitis included hydroxyurea, vincristine, cytosine-arabinoside, methotrexate, all-trans retinoic acid, granulocyte-colony stimulating factor, interferon and antibiotics. Paraneoplastic vasculitis is not rare in leukemias and may be a manifestation of the blastic phase of chronic myeloid leukemia. Furthermore paraneoplastic vasculitis can be fatal in myelodysplastic syndromes and may be present clinically before the specific diagnosis is made. Drugs used in routine therapy may be the cause of the vasculitis, thus skin biopsy should be performed in all cutaneous lesions in patients with hemopoietic neoplasias.
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PMID:Vasculitis and leukemia. 1142 10

In an attempt to improve induction chemotherapy for older patients with acute myeloid leukemia (AML),1314 patients were randomized to 1 of 3 induction treatments for 2 courses of DAT (daunorubicin, cytarabine, and thioguanine) 3 + 10, ADE (daunorubicin, cytarabine, and etoposide) 10 + 3 + 5, or MAC (mitoxantrone-cytarabine). The remission rate in the DAT arm was significantly better than ADE (62% vs 50%; P =.002) or MAC (62% vs 55%; P =.04). This benefit was seen in patients younger and older than 70 years. There were no differences between the induction schedules with respect to overall survival at 5 years (12% vs 8% vs 10%). A total of 226 patients were randomized to receive granulocyte colony-stimulating factor (G-CSF) or placebo as supportive care from day 8 after the end of treatment course 1. The remission rate or survival were not improved by G-CSF, although the median number of days to recover neutrophils to 1.0 x 10(9)/L was reduced by 5 days. Patients who entered remission (n = 371) were randomized to stop after a third course (DAT 2 + 7) or after 6 courses, ie, a subsequent COAP (cyclophosphamide, vincristine, cytarabine, and prednisolone), DAT 2 + 5, and COAP. The relapse risk (81% vs 73%), disease-free survival (16% vs 23%), and overall survival at 5 years (23% vs 22%) did not differ between the 3-course or 6-course arms. In addition to a treatment duration randomization, 362 patients were randomized to receive 12-month maintenance treatment with low-dose interferon, but no benefit was seen with respect to relapse risk, disease-free survival, or overall survival.
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PMID:Attempts to improve treatment outcomes in acute myeloid leukemia (AML) in older patients: the results of the United Kingdom Medical Research Council AML11 trial. 1152 Jul 75

The interferon response genes 1 and 2 have been shown to be involved in the regulation of differentiation and proliferation of cells of the myeloid series, with the former functioning as an anti-oncogene and the latter as an oncogene. In the study described here, the levels of expression of these two genes and the ratio of their expression were compared in AML and normal marrow. The ratio of gene expression was significantly less in AML marrow cells as compared to normal marrow cells [med ratio = 1.33 vs. 2.97, P = 0.003]. While the expression ratio was unaffected by the presence or absence of either ras or fms mutations, p53 mutations were associated with higher IRF1:IRF2 expression ratios that wt p53 genes [med = 1.701 vs. 1.135, P = 0.014]. Given the functional characteristics and the competitive nature of these two genes, it is possible that leukemic transformation is associated with a fall in IRF1:IRF2 ratios. Finally, the administration of IL4 can result in the normalization of the IRF1:IRF2 ratio in the marrow cells of some patients with AML.
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PMID:Alterations in IRF1/IRF2 expression in acute myelogenous leukemia. 1155 33

The effect of recombinat human granulocyte-macrophage colony-stimulating growth factor (rHuGM-CSF) treatment on in vitro interferon (IFN) and tumor necrosis factor (TNF) production in peripheral blood cells of 46 patients with acute myelogenous leukemia (AML) was examined. GM-CSF significantly enhanced virus-induced IFN-alpha production in blood cells (containing 68% of blasts) of 28 patients with M4-M5 AML according to the French-American-British (FAB) classification and also phytohemagglutinin (PHA)-induced IFN-gamma production in blood cells (containing 70% of blasts) of 18 patients with AML MO-M3 type. In control blood cells (25 healthy persons) GM-CSF enhanced PHA-induced IFN-gamma but did not influence IFN-alpha production. In the presence of GM-CSF, TNF-alpha titers induced with lipopolysaccharide were also higher in control blood cells but not in cells of patients with M0-M3 or M4-M5 type of AML. The significance of GM-CSF-enhanced IFN-alpha and IFN-gamma production in antimicrobial and anti-leukemic immune reactions which can develop during GM-CSF therapy is discussed.
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PMID:Effect of granulocyte-macrophage colony-stimulating growth factor on interferon and tumor necrosis factor production in whole blood cell cultures of patients with acute myelogenous leukemia. 1166 52

Current conventional treatment for patients with acute myelogenous leukemia results in a high percentage of clinical responses in most patients. However, a high percentage of patients still remain refractory to primary therapy or relapse later. This review examines the search for new agents and new modes of therapy. In Section I, Dr. Estey discusses new agents directed at various targets, such as CD33, angiogenesis, inappropriately methylated (suppressor) genes, cell cycle checkpoints, proteosomes, multidrug resistance (MDR) gene, mitochondrial apoptotic pathway. He also reviews preliminary results of phase I trials with the nucleoside analog troxacitabine and liposomal anthracyclin and suggests new strategies for trials of new agents. In Section II, Dr. Jones revisits differentiation therapy and presents results of preclinical and clinical studies that demonstrate that a variety of clinically applicable cell cycle inhibitors (interferon, phenylbutyrate, vitamin D, retinoids, bryostatin-1) preferentially augments growth factor-mediated induction of myeloid leukemia terminal differentiation, as well as blocks growth factors' effects on leukemia proliferation. The combination of cell cycle inhibition plus myeloid growth factors may offer a potential treatment for resistant myeloid leukemias. In Section III, Drs. Levitsky and Borrello address the question of tumor vaccination in AML and shows that, although tumor rejection antigens in AML have not been formally identified to date, a growing number of attractive candidates are ripe for testing with defined antigen-specific vaccine strategies. Interestingly, the ability to drive leukemic blasts to differentiate into competent antigen presenting cells such as dendritic cells may be exploited in the creation of cellular vaccines. Ultimately, the successful development of active immunotherapy for AML will require integration with dose-intensive chemotherapy, necessitating a more complete understanding of host immune reconstitution. In Section IV, Dr. Slavin reviews the concept of delivering non-myeloablative stem cell transplantation (NST) and delayed lymphocyte infusion (DLI) to increase tolerance in particular in high risk and older patients, and take advantage of the graft-versus-leukemia (GVL) effect. All these approaches hold promise in reducing morbidity and mortality and differ from the older concepts aiming at delivering the highest possible doses of chemotherapy and/or total body irradiation to reach maximum leukemia cell kill, whatever the toxicity to the patient.
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PMID:New Developments in the Therapy of Acute Myelocytic Leukemia. 1170 36

We report a patient with Philadelphia chromosome positive (Ph +ve) chronic myelogenous leukemia (CML), treated with hydroxyurea alone, who upon disease progression developed an additional Ph - ve clone containing chromosomal abnormalities typical of myelodysplastic syndrome (MDS). Retrospective analysis of a cryopreserved stem cell specimen from diagnosis confirmed that this second clone developed during the course of treatment. The development of a clone with additional cytogenetic abnormalities in CML has only been reported after leukemogenic treatment, stem cell transplantation or interferon. We report a case of secondary Ph - ve MDS/AML during blast crisis in a patient treated with hydroxyurea for CML.
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PMID:Coexistence of independent myelodysplastic and Philadelphia chromosome positive clones in a patient treated with hydroxyurea. 1183 90

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