Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0002871 (anemia)
 52,094 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The antiviral drug used in the treatment of acquired immunodeficiency syndrome, zidovudine, has proved effective in ameliorating the morbidity and mortality associated with human immunodeficiency virus infection. However, associated with zidovudine is the development of severe bone marrow toxicity manifested by anemia, neutropenia, and occasionally thrombocytopenia. We report the results of studies that demonstrate the ability of basic fibroblast growth factor (B-FGF) to reduce zidovudine toxicity to several classes of hematopoietic progenitors (granulocyte-macrophage, CFU-GM; megakaryocyte. CFU-Meg; and erythroid, BFU-E) from normal murine, human, and murine retrovirus-infected bone marrow cells when cocultured with zidovudine in vitro. Optimal response to B-FGF was observed at a dose concentration of 10 ng/ml. The specificity of B-FGF was demonstrated in the presence of protamine sulfate, an effective inhibitor of B-FGF mitogenic activity. In addition, synergistic activity of B-FGF on zidovudine-induced hematopoietic stem cell toxicity was observed in the presence of interleukin 1 (IL-1) (30 ng/ml). These studies demonstrate that B-FGF is capable of reducing the hematopoietic toxicity associated with zidovudine and that such an effect can be amplified in the presence of IL-1.
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PMID:In vitro modulation of the toxicity associated with the use of zidovudine on normal murine, human, and murine retrovirus-infected hematopoietic progenitor stem cells with basic fibroblast growth factor and synergistic activity with interleukin-1. 131 78

The influence of recombinant human erythropoietin (rHu-EPO) on anaemia and bone marrow cells was investigated in 7 patients with terminal renal failure on maintenance haemodialysis. The examination was performed immediately prior to rHu-EPO treatment (mean hematocrit 20.3%) and after increase of hematocrit to 33%. An increased number of cells from the erythroblastic series and rejuvenation of this population were observed during the treatment. There was no significant influence of the treatment on the myeloblastic cells series. An increase in megakaryocyte activity was observed in 2 studied patients.
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PMID:[Effect of recombinant human erythropoietin on the bone marrow picture in patients with chronic renal failure treated by hemodialysis]. 143 2

We studied the long-term effect of continued zidovudine exposure in mice on hematopoiesis, as determined by peripheral blood indices, assays of erythroid (colony-forming unit-erythroid [CFU-E] and burst-forming unit-erythroid [BFU-E]), myeloid (CFU-granulocyte-macrophage [GM]), megakaryocyte (CFU-Meg), and plasma titers of erythropoietin, granulocyte-macrophage colony-stimulating factor, megakaryocyte colony-stimulating factor, and tumor necrosis factor-alpha. Dose-escalation of zidovudine (0.1, 1.0, and 2.5 mg/ml) induced a dose-dependent decrease in hematocrit, white blood cells, and platelets. High-dose drug, i.e., greater than 1.0 mg/ml, reduced marrow CFU-E; splenic CFU-E was increased after 1 week, then declined. BFU-E was increased at Weeks 1 and 2, then declined to control levels. Splenic BFU-E rose during the examination period that was dose-dependent. Femoral CFU-GM was cyclic, i.e., low-dose drug, 0.1 mg/ml, was increased gradually, the declined; higher doses of 1.0 and 2.5 mg/ml were lower until Week 5, then were above controls. Splenic CFU-GM was increased initially at Week 2 (1.0 mg/ml), then declined; the higher dose (2.5 mg/ml) increased initially, then declined below controls (Week 6). Femoral CFU-Meg was increased after low-dose drug and inhibited after high dose (2.5 mg/ml). Splenic CFU-Meg was reduced initially, followed by an increase at Week 4. Plasma titer of erythropoietin was elevated, proportional to dose escalation of drug, and inversely proportional to the hematocrit. No difference was observed in plasma levels of granulocyte-macrophage colony-stimulating factor, megakaryocyte colony-stimulating factor, or tumor necrosis factor-alpha. This study demonstrates that zidovudine-induced anemia results from: (i) inadequate numbers of bone marrow-derived, erythropoietin-dependent hematopoietic progenitors, i.e., CFU-E; and (ii) a shift in erythropoietin-responsive progenitors from bone marrow to spleen capable of responding to obligatory growth factors.
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PMID:Suppression of murine hematopoiesis in vivo after chronic administration of zidovudine: evidence that zidovudine-induced anemia is the result of decreased bone marrow-derived, erythropoietin-responsive progenitor cells. 154 25

A folate-free amino acid-based diet provided an opportunity to characterize the effects of folate depletion on growth, tissue folate levels, and hematopoiesis of mice under well-standardized conditions. Weanling mice were fed a folate-free, amino acid-based diet supplemented with either 0 or 2 mg folic acid/kg diet for 35 to 48 days. Folate concentrations were decreased in liver, kidney, serum, and erythrocytes in mice fed the folate-free diet. The folate-deficient mice had anemia, reticulocytopenia, thrombocytopenia, and leukopenia, all of which reverted to normal after folic acid was reintroduced to the diet. Hematopoietic organs of folate-deficient mice had alterations that were similar to those seen in folate-deficient humans except that in mice, the hyperplasia of hematopoietic tissue occurred in the spleen rather than in the marrow. Ferrokinetic studies showed a normal 59Fe-transferrin half-life, but the percentage of 59Fe-incorporation into red blood cells at 48 hours was markedly subnormal. The number of committed hematopoietic progenitors at the stages of erythroid colony-forming units (CFUs), megakaryocyte CFUs, and granulocyte-macrophage CFUs were all increased in folate-deficient mice. However, the progeny of these progenitors was markedly decreased in folate-deficient mice. Thus, the folate-deficient mice had "ineffective hematopoiesis" leading to pancytopenia, and they therefore provide a murine model of megaloblastic anemia.
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PMID:Ineffective hematopoiesis in folate-deficient mice. 157 42

Both large, acute doses of erythropoietin (EPO) and short-term hypoxia increase platelet counts in mice, but long-term hypoxia causes thrombocytopenia. Therefore, we tested the hypothesis that EPO injected in large, chronic doses (a total of 80 U of EPO over a 7-day period) might cause thrombocytopenia. EPO caused increased red blood cell (RBC) production, ie, increased hematocrits, RBC counts, mean cell volume (MCV), and reticulocyte counts (from P less than .05 to P less than .0005), and decreased thrombocytopoiesis, ie, decreased platelet counts, percent 35S incorporation into platelets, and total circulating platelet counts (TCPC) (P less than .0005). Femoral marrow megakaryocyte size was unchanged, but megakaryocyte number was significantly (P less than .005) reduced in mice treated with EPO. EPO-injected mice had increased spleen volumes (P less than .0005), but blood volumes (BV) were unchanged. In EPO-treated, splenectomized mice, RBC production was also increased (P less than .05 to P less than .0005) and platelet counts, TCPC, and percent 35S incorporation into platelets were decreased (P less than .05), but BV was not altered. Therefore, the decrease in platelet counts observed in EPO-treated mice was not due to increased BV or to an enlarged spleen. In other experiments, mice were rendered acutely thrombocytopenic to increase thrombocytopoiesis, and platelet and RBC production rates were determined. In mice with elevated thrombocytopoiesis, RBC counts, hematocrits, percent 59Fe RBC incorporation values, and MCV were decreased (P less than .05 to P less than .0005). Because 59Fe RBC incorporation and MCV were not elevated, the decrease in RBC counts and hematocrits does not appear to be due to bleeding. Therefore, we show that large, chronic doses of EPO increase erythropoiesis and decrease thrombocytopoiesis. Conversely, acute thrombocytopenia causes increased thrombocytopoiesis and decreased erythropoiesis. These findings support the hypothesis of competition between precursor cells of the erythrocytic and megakaryocytic cell lines (stem-cell competition) as the cause of thrombocytopenia in EPO-treated mice and the cause of anemia in mice whose platelet production rates were increased.
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PMID:Large, chronic doses of erythropoietin cause thrombocytopenia in mice. 129 64

Paroxysmal nocturnal haemoglobinuria (PNH) was diagnosed in a 20-year-old male patient who suffered from anaemia since the age of 11. Eighteen years after diagnosis, PNH transformed into refractory anaemia with ringed sideroblasts (RARS). Trisomy 8 was observed in 27%, 45% and 53% of the bone marrow metaphase cells analysed in 1987, 1988 and 1990 respectively. In order to determine which bone marrow cell lineages were affected by trisomy 8 and at which stage of stem cell differentiation, MAC (Morphology, Antibody, Chromosomes) and CISS (Chromosomal In Situ Suppression) hybridization techniques were combined. The MAC technique enables karyotypic analysis of morphologically and immunologically classified mitotic cells. CISS hybridization makes it possible to detect individual chromosomes and chromosome aberrations using recombinant DNA libraries from sorted human chromosomes. Trisomy 8 was detected in granulomonocytic (50.6%), erythrocytic (67.2%) and megakaryocytic (one megakaryocyte with trisomy 8, one normal) lineages, providing evidence for the occurrence of trisomy 8 in early haematopoietic cell precursors, at the GEMM or pluripotent level. Cytogenetic and clinical data suggest that the sideroblastic clone originated from a mutation affecting a cell of the PNH clone, progressively replaced by the PNH/RARS clone, due to proliferative advantage.
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PMID:Trisomy 8 detection in granulomonocytic, erythrocytic and megakaryocytic lineages by chromosomal in situ suppression hybridization in a case of refractory anaemia with ringed sideroblasts complicating the course of paroxysmal nocturnal haemoglobinuria. 164 28

Forty-eight patients with refractory anemia (RA) were retrospectively analyzed for their prognosis and subclassified into three groups: 12 patients with hematological improvement (A), 23 patients with no changes (B), and 13 patients with progression to RAEB or acute leukemia (C). For all patients, the median survival were 49.2 months, and the rate of leukemic transformation was 16%. The median survivals were 60.6, 32.1, and 17.9 months, respectively, for groups A, B and C. The factors indicating poor prognosis were low reticulocyte counts, low neutrophil alkaline phosphatase activity, low% red cell utilization, high M/E ratio, high blast percentage in the bone marrow and cytological abnormalities in the granulocyte and megakaryocyte series. By using multiple discriminant analysis, we obtained a formula for the prognostic estimation with a discrimination probability of 62.5%. This formula could predict either the patients with good (Y greater than 0.85) or poor (Y less than 0.59) prognosis, and might be useful to select the treatment for this intractable anemia at the time of diagnosis.
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PMID:[Multiple discriminant analysis for prognosis of refractory anemia]. 194 20

From 1982 to 1985, four cases of primary myelofibrosis were diagnosed in our department. Three were boys and one was a girl. Their ages ranged from 7 months to 15 years. The diagnosis was made based on anemia, leukoerythroblastic change and presence of giant platelets in the peripheral blood, and a bone marrow biopsy showing myelofibrosis. Most of them had anemia, fever, and hepatosplenomegaly on admission. The anemia was severe and refractory to repeated transfusions and steroid therapy in 3 out of the 4 cases. Splenectomy was performed in 1 case, but without satisfactory results. The clinical course and blood pictures in one case resembled leukemia of megakaryocyte lineage (M7), but results of marker studies of the blast cells ruled out the possibility of M7. Three of them underwent leukemic transformation within 2 years and died soon after. The other one died of sepsis 2 weeks after diagnosis. Myelofibrosis in childhood occurs rarely, however, when it does, it always runs a rapid and fatal course.
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PMID:Primary myelofibrosis in children: report of 4 cases. 198 Dec 37

The Belgrade laboratory (b/b) rat has a hereditary hypochromic microcytic anemia because of defective transmembrane iron transport into erythroblasts. The present study was prompted by our previous work in which we showed that the b/b rat has hypomegakaryocytic thrombocytopenia associated with increased megakaryocyte size. To define the basic mechanism underlying this abnormality in the b/b rat we have studied both megakaryocytopoiesis and granulopoiesis in anemic b/b rats, chronically transfused b/b rats, iron-treated b/b rats, and controls. We have found decreased concentrations of megakaryocyte and granulocyte progenitors in the marrow of b/b rats. Full correction of the severe anemia by chronic transfusion resulted in normalization of megakaryocyte progenitors, small acetylcholinesterase positive cells, megakaryocyte size, and platelet counts, along with granulocyte progenitors. In contrast, the partial correction of anemia obtained by iron treatment resulted in improvement, but not normalization, of these parameters. These findings indicate that abnormal megakaryocytopoiesis in the b/b rat can be best interpreted as a consequence of hypoxia because of the severe anemia. Because we have recently shown that the number of erythroid progenitors in b/b rats is also low, we propose that abnormal megakaryocytopoiesis in this animal is a reflection of an acquired stem cell disorder induced by the prolonged hypoxia resulting from the severe anemia.
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PMID:Abnormal megakaryocytopoiesis in the Belgrade laboratory rat. 199 Nov 62

Despite major advances in supportive care, neutropenic infections and thrombopenic bleedings remain major lethal treatment- and disease-related complications in patients with malignancy. Moreover, complications of platelet (Plt) and erythrocyte transfusion therapy have become a cause of great concern and shortages of homologous blood products are a constant problem. Suggestions that the application of recombinant human hemopoietins may provide an alternative treatment modality in this patient population is currently being evaluated in clinical trials. Erythropoietin (EPO) has been shown to be effective in the treatment of anemia in patients with bone marrow, infiltrating low-grade non-Hodgkin's lymphoma, multiple myeloma, and in some patients with myelodysplastic syndrome. Preliminary data suggest that subcutaneous administration of EPO results in a higher slope of increasing erythropoietic parameters compared to intravenous administration. Protective effects on normal erythropoiesis have been attributed to EPO in patients receiving chemotherapy. The finding of EPO receptors on megakaryocytes supports the clinical observation of increased Plt production associated with decreased bleeding and transfusion frequencies in a substantial number of patients receiving EPO. Clinical trials with granulocyte-macrophage (GM-CSF) and granulocyte colony stimulating factor (G-CSF) have reached phase III trials. Both factors show high efficacy to shorten or improve neutropenia related to chemotherapy, bone marrow transplant, or underlying disease. Mechanisms responsible for mucosa protection and improved healing of mucositis observed with both factors remain undetermined yet phase I/II evaluation of IL-3 shows multilineage hemopoietic responses including myeloid, erythroid, and megakaryocyte lineages. Possible anti-cancer effects of hemopoietins achieved by direct action or by increased chemotherapy intensity are currently under investigation.
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PMID:Hemopoietins in clinical oncology. 204 61


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