UMLS:C0002874 - FACTA Search

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Query: UMLS:C0002874 (aplastic anemia)
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The aim of this study was to measure the level of cytokines produced by peripheral blood mononuclear cells (PBMNC) in patients with aplastic anemia (AA) and determine their effect on normal bone marrow (BM) colony growth. Thirty-five patients with AA and 21 normal controls were enrolled in the study. Medium conditioned by PBMNC of AA patients in the presence of phytohemagglutinin (PHA) was found to be suppressive to the clonal growth of normal BM cells. Thus, we further determined the presence in the PBMNC conditioned medium (CM) of inhibitory cytokines (macrophage inflammatory protein-1 alpha [MIP-1 alpha], transforming growth factor-beta 2 [TGF-beta 2], interferon-gamma [IFN-gamma], and tumor necrosis factor-alpha [TNF-alpha]) and stimulatory cytokines (granulocyte-macrophage colony-stimulatory factor [GM-CSF], interleukin-3 [IL-3], and stem cell factor [SCF]). The results show no significant difference between AA patients and normal controls in the spontaneous production of all cytokines by PBMNC. After PHA stimulation, the production of MIP-1 alpha, IFN-gamma, TNF-alpha, and GM-CSF significantly increased in the cultures of AA patients (p = 0.0009, 0.0002, 0.0022, and 0.0156, respectively). However, both TGF-beta 2 and SCF were undetectable in most of the tested samples. IL-3 was measured in the conditioned medium only after PHA stimulation, but without significant difference between the two groups (p = 0.67). Furthermore, the myelopoietic suppressing effect of AA-PBMNC CM could be significantly blocked by pretreatment with specific antibodies to the corresponding inhibitory cytokines (MIP-1 alpha, IFN-gamma, and TNF-alpha). After antibody neutralization, an apparent change occurred in the clonal growth of normal BM cells incubated with AA-PBMNC CM, resulting in colony enhancement of 205, 131, and 237% by anti-MIP-1 alpha, anti-IFN-gamma, and anti-TNF-alpha, respectively. These results suggest that overproduction of inhibitory cytokines, rather than underproduction of stimulating cytokines, may play a role in the progression of at least some patients with AA.
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PMID:Production of hematopoietic regulatory cytokines by peripheral blood mononuclear cells in patients with aplastic anemia. 853 89

Rejection after allogeneic BMT for aplastic anemia is a complication with a high risk of mortality. We describe a patient who, following a second episode of rejection after a second BMT entered a third durable remission subsequent to treatment with ALG, donor lymphocyte infusions, GM-CSF, and erythropoietin. Therapy was well tolerated. At 5 years after rejection treatment, his hematopoiesis is of complete donor origin as determined by analyses of short tandem repeats. Thus, donor lymphocyte infusions can be considered as a therapy option for marrow rejection after allogeneic BMT for aplastic anemia.
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PMID:Rejection of the second allogeneic graft in a patient with severe aplastic anemia reversed by antilymphocyte globulin and donor lymphocyte infusions. 897 92

Cytokines, by definition, exert an effect on haematopoiesis. Diseases characterized by haematopoietic insufficiency, such as aplastic anaemia, should therefore be investigated for abnormal expression of these regulatory proteins. In studies on hairy cell leukaemia, a severe deficiency was found in the production of interleukin-3 (IL-3), granulocyte-macrophage colony stimulating factor (GM-CSF), granulocyte CSF, IL-6 and tumour necrosis factor alpha (TNF alpha). Further studies on IL-6 at the mRNA and protein levels revealed that peripheral blood mononuclear cells and even hairy cells could be stimulated by interferon alpha (IFN alpha) to produce IL-6. It is interesting to speculate on the beneficial effects of IFN alpha therapy on the expansion of normal haematopoiesis and suppression or even elimination of malignant cells. Studies on a patient with angio-immunoblastic lymphadenopathy, another disease showing haematopoietic insufficiency, who developed severe aplastic anaemia, showed massive increases in IFN gamma and TNF alpha levels in serum; IL-6 and GM-CSF levels were below the limit of detection. These results correlated with an abnormal distribution of CD4+ and CD8+ T lymphocytes in the patient's blood and were compatible with the suppressive effects of IFN gamma and TNF alpha on haematopoiesis.
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PMID:The role of cytokines in haematopoiesis. 898 45

We report the results of 23 patients with aplastic anemia (AA) treated with a program of 14 lymphocytapheresis (LC). Treatments were performed with apheresis machines, models Haemonetics 30-S and Baxter CS3000, using the standard program. This procedure was done because AA in many cases appears as a result of the action of a T cell population that inhibits hematopoiesis. Theoretically, removal of this clonal population would produce hematopoietic recovery. Of the total of 23 patients, 9 were excluded for final evaluation of treatment results because 7 died during or shortly after treatment (0.7-3 months); one patient abandoned treatment after three LC and another died 7 months later because of transformation to acute leukemia. The remaining 14 patients were included in the final evaluation of treatment; seven females and seven males, average age 46.1 years (range 22-69); 13 with severe, and one with moderate AA; 11 with recently diagnosed, and 3 with chronic AA; 12 without previous treatment and two treated before with antilymphocyte globulin + oxymetholone (OXM) + cyclosporine A (CsA) with transient partial remission (PR). Besides lymphocytapheresis, 13 patients received OXM; 4 of them GM-CSF and one low dose CsA. Four patients had complete remission lasting > 59.5 months (range 42-78); eight PR (average duration of > 38.6 months), and two minimal remission (> 37 and 29 months). Platelet, reticulocyte and granulocyte counts increased on average at 48.7, 73.3 and 91.4 days, respectively. In conclusion, 14 (60.8%) of 23 patients with AA showed an improvement related to LC treatment, with a survival probability of 63% from the fourth month, the latter with an added beneficial effect of the other therapies used. Larger numbers of patients have to be treated with LC to determine its real usefulness, mechanism of action and the best conditions for its use.
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PMID:Treatment results of 23 cases of severe aplastic anemia with lymphocytapheresis. 907 93

A 19-year-old male underwent allogeneic BMT for severe aplastic anaemia (SAA) from his HLA- and blood group-identical sister. He was conditioned with cyclophosphamide (CY) and single fraction total lymphoid irradiation (TLI). GVHD prophylaxis consisted of FK506 and a short course of methotrexate. The patient failed to achieve durable trilineage hematopoietic engraftment. There was no significant myeloid response to GM-CSF or G-CSF. Evaluation of FACS-sorted peripheral T cells from the patient by fluorescence in situ hybridization (FISH) revealed mixed chimerism (44% host origin). Fifty-three days after the first BMT, he was treated with G-CSF primed, unmanipulated PBSC transfusions (5.28 x 10(8)/kg mononuclear, 4.28 x 10(6)/kg CD34+, 292.51 x 10(6)/kg CD3+ cells) from his original donor without reconditioning. FK506 was continued at the same dose. Neutrophil recovery to 0.5 x 10(9)/l and platelet engraftment to 20 x 10(9)/l was achieved 11 and 27 days following the first dose of allogeneic PBSC transfusion, respectively. On day 23 a repeat FISH on the patient's sorted peripheral T lymphocytes revealed 91% donor origin T cells. The patient is currently well with a stable engraftment 6 months following allogeneic PBSC transfusion, with no signs of acute of chronic GVHD.
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PMID:Successful engraftment after primary graft failure in aplastic anemia using G-CSF mobilized peripheral stem cell transfusions. 911 16

In vitro priming of T cell with horse antilymphocyte globulin (HALG) results in cytokine release, and this has been associated with its clinical efficacy in patients with severe aplastic anaemia (SAA). Rabbit antithymocyte globulin (RATG) has been studied less extensively. In this study we compare the in vitro priming effect of HALG and RATG on purified normal marrow T cells: end-points of the study were 1) levels of TNF-alpha (TNF-alpha), IFN-gamma (IFN-gamma) GM-CSF in T cell supernatants, and 2) effect of T cell supernatants on colony formation with or without exogenous GM-CSF TNF-alpha, IFN-gamma and GM-CSF levels were comparable for HALG, RATG and phytohaemagglutinin (PHA). T cell supernatants showed comparable enhancement of colony formation in the presence of recombinant human GM-CSF (rhGM-CSF) and supported colony forming unit granulomacrophage (CFU-GM) growth in the absence of growth factor. This study shows that horse and rabbit derived ALG/ATG and PHA have a comparable in vitro priming effect on T cells: both agents should probably be tested for their clinical efficacy in SAA patients.
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PMID:Comparable TNF-alpha, IFN-gamma and GM-CSF production by purified normal marrow CD3 cells in response to horse anti-lymphocyte and rabbit antithymocyte globulin. 957 77

An abnormal bone marrow microenvironment and hematopoietic growth factors are considered as one of the possible mechanisms of aplastic anemia. Circulating levels of erythropoietin, granulocyte colony-stimulating factor (G-GSF), granulocyte-macrophage colony-stimulating factor (GM-GSF) and thrombopoietin are significantly higher in patients with aplastic anemia than in normal controls. Of the two hematopoietic growth factors, acting at the early stages of hematopoiesis, circulating levels of flt-3 ligand are highly elevated in patients with aplastic anemia, whereas those of stem cell factor (SCF) are essentially normal. Decreased production has been described only for interleukin (IL) 1. This may reflect defective monocyte-macrophage maturation in patients with aplastic anemia. Marrow stromal cells are thought to exert a regulatory role in hematopoiesis, at least in part, by the production of certain hematopoietic growth factors. The abilities of stromal cells to produce hematopoietic growth factors, including G-GSF, GM-CSF, IL-6 and SCF, are either normal or elevated in the majority of patients. Thus, the deficiencies of hematopoietic growth factors are unlikely to be the cause of aplastic anemia.
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PMID:Hematopoietic growth factors and marrow stroma in aplastic anemia. 971 65

Recombinant human megakaryocyte growth and development factor (rHuMGDF), a truncated form of the Mpl ligand, stimulates megakaryopoiesis both in vitro and in vivo. We describe the in vitro effect of pegylated recombinant human MGDF (PEGrHuMGDF) alone and in combination with other haemopoietic growth factors (G-CSF, GM-CSF, IL3, IL6, erythropoietin, SCF) on megakaryopoiesis in bone marrow from 11 normal subjects and 19 patients with aplastic anaemia (AA). We used semi-solid cultures to assess megakaryocyte colony growth (CFU-Mk) and 7 d suspension cultures to assess production of platelet glycoprotein IIIa (CD61) positive cells. CFU-Mk growth from normal marrow increased 3-4-fold and CD61+ve cells in suspension culture increased 8-10-fold with the addition of 10 ng/ml PEGrHuMGDF. In normal subjects growth factor combinations further increased responses in suspension culture, PEGrHuMGDF + SCF, PEGrHuMGDF + IL3 and PEGrHuMGDF + SCF + IL3 + Epo (P<0.05). IL6, GM-CSF, G-CSF or Epo added with PEGrHuMGDF did not consistently give this increase. CFU-M. growth from AA marrow remained very low in the presence of PEGrHuMGDF, with or without the addition of other growth factors. CD61+ve cells in suspension culture were, however, increased in the presence of PEGrHuMGDF alone in 12/19 AA cases. Of the 12 patients responsive to PEGrHuMGDF, nine were tested with additional growth factors and further responses were seen in six. In the AA cases PEGrHuMGDF+SCP and PEGrHuMGDF+SCF+IL3+Epo gave the highest responses. These data suggest that PEGrHuMGDF, alone or in combination with SCF and/or IL3, can enhance megakaryocyte proliferation in some patients with aplastic anaemia and may therefore have a role in the treatment of thrombocytopenia in these cases.
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PMID:The in vitro effect of pegylated recombinant human megakaryocyte growth and development factor (PEGrHuMGDF) on megakaryopoiesis in patients with aplastic anaemia. 1002 23

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

In order to determine the relationship between bone marrow (bm) endosteal cells (EDC) and hemopoietic progenitors, we have analyzed the immunophenotype of EDC using various antibodies (Ab) against mesenchymal antigens. The Ab were applied on paraffin sections of normal bm (iliac crest, n=17; talus, n=1; phalanx, n=1), myeloregenerative bm (after chemotherapy), and hematologic disorders (acute myeloid leukemia (AML), n=8; chronic myeloid leukemia (CML), n=6; myelodysplastic syndromes (MDS), n=14; severe aplastic anemia (SAA), n=4; essential thrombocythemia (ET), n=2; idiopathic (primary) osteomyelo-fibrosis (IMF), n=1; polycythemia vera (PV), n=1). In normal bm, EDC were found to react with Ab against vimentin, tenascin, alpha-smooth muscle actin, osteocalcin, CD51, and CD56, but did not react with Ab against CD3, CD15, CD20, CD34, CD45, CD68, or CD117. An identical phenotype of EDC was found in AML, MDS, SAA, ET, IMF, PV, myeloregenerative bm, and peripheral bones lacking active hemopoiesis (talus, phalanx). In patients with CML, EDC reacted with Ab to CD51, but did not react with Ab to CD56. Based on their unique antigen profile, EDC were enriched from normal bm by enzyme digestion and cell sorting. However, these enriched cells (CD56+, CD45-, CD34-) did not give rise to hemopoietic cells under the culture conditions used, i.e. in the presence of the growth factors IGF-1, bFGF, SCF, IL-3, and GM-CSF Together, our data do not support the hypothesis that EDC are totipotent mesenchymal progenitors giving rise to hemopoietic cells.
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PMID:Immunophenotypic characterization of human bone marrow endosteal cells. 1039 6

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