UMLS:C0023467 - FACTA Search

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Query: UMLS:C0023467 (acute myeloid leukemia)
35,200 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Rabbit or goat antisera directed to ALL, CLL, AML and CML cells were investigated in cytotoxicity tests with different leukaemia and normal cells as targets. After absorptions with erythrocytes and spleen cells from allogeneic donors the antisera killed only leukaemia cells. There was no reaction with remission leukocytes or blood leukocytes from normal donors. Anti-ALL-Sera reacted in 35 out of 49 tests with ALL cells from 13 patients. Apparently the ALL antisera which were directed to the T cell subtype of ALL preferentially affected ALL cells of this subtype. Cross reactions with cells from CLL, AML and CML were not found. Anti-CLL-sera reacted in 10 out of 12 tests with CLL cells from 4 donors, and in 4 out of 20 tests with ALL cells from 7 donors and also with the cells of a CML patient. AML cells from two patients were not killed. Antisera against AML and CML showed extensive cross reactions with cells of myelocytic and lymphocytic leukaemias. Absorption tests demonstrated the presence of two antibody specificities in AML antisera, one of which being directed to a common antigen of AML and ALL cells and another against an antigen of myelocytic leukaemia cells.
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PMID:Specificities of heterologous antisera against human leukaemia cells. 1. Reactions against leukaemia cells. 8 65

Antisera against human acute myelocytic leukaemias were tested in complement-dependent in-vitro cytotocity tests against leukaemia cells and normal cells as targets. After absorption with erythrocytes and spleen cells from allogeneous donors the antisera reacted with leukaemia cells, but not with leukocytes from bone marrow and the peripheral blood of children in remission, lymphocytes from healthy donors, enriched B-lymphocytes, enriched T-lymphocytes, PHA-induced blasts and cord blood lymphocytes. Extensive cross reactions were obtained in the tests against leukaemia cells. The antisera reacted not only with AML cells, but also with ALL, CLL, and CML cells. It was possible to remove the cross-reactivity with ALL cells through absorption with ALL cells or with fetal tissue, and to remove the cross reactivity with CLL cells through absorption with CLL. A complete absorption of the anti-AML sera was possible with AML and CML cells. After absorption with fetal tissue and CLL cells the antisera showed exclusively specificity for myelocytic leukaemias. Thus, AML cells contain three leukaemia-associated membrane antigen components: an antigen of fetal origin, a "CLL-specific" antigen, and an antigen that occurs on myelocytic leukaemias.
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PMID:Human leukaemia-associated antigens expressed by acute myelocytic leukaemia cells and their detection by heterologous antisera. 8 82

Antisera from rabbits and goats against subtypes of acute lymphocytic leukaemia (ALL with T-cell markers, ALL with B-cell markers, Non-T-non-B ALL) were tested for their specificity in complement-dependent in-vitro cytotoxicity testing. After absorption of the fivefold diluted antisera with erythrocytes and spleen cells of allogenous donors they reacted with ALL cells, but not with leukaemias of other types (AML, CLL, CML), lymphocytes of healthy donors, enriched B-lymphocytes, enriched T-lymphocytes, PHA-stimulated lymphocytes, cord lymphocytes and bone marrow lymphocytes of patients in remission. In the reactions of the antisera against ALL cells the subtype of ALL is of major importance: Six rabbit antisera and one goat antiserum against T-subtype ALL reacted in all 19 tests with the leukaemia cells of 5 patients with T-cell ALL and in all 9 tests with thymocytes of 3 donors, but only in 14 out of 41 tests with the leukaemia cells of 14 Non-T-non-B ALL patients. One antiserum against a B-subtype ALL lysed B-cell ALL (1/1), but not T-cell ALL (0/3), Non-T-non-B-cell ALL (1/5) and thymocytes (0/2). Four antisera against Non-T-non-B-subtype ALL reacted in 22 out of 46 tests with the Non-T-non-B cells of 17 ALL patients, but did not react with the leukaemia cells of 4 children with T-cell ALL (0/16), one child with B-cell ALL (0/1) thymocytes of 2 donors (0/4). The reactions of the anti-ALL sera with fetal liver cells, complete absorbability of the antileukaemic activity of the antisera with fetal tissue and the reactions of an anti-fetal serum with ALL cells point to the existence of fetal antigen components as leukaemia-associated antigens.
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PMID:Human leukaemia-associated antigens expressed by acute lymphocytic leukaemias and their detection with heterologous antisera to T, B-, and non-T-non-B subtype AL blasts. 8 83

The incidence of amoeboid movement configuration (AMC), a cell shape suggestive of cell locomotion at the moment of fixation, has been studied in the tumour cells of bone marrow smears from leukaemia patients at the time of diagnosis. The groups of patients with CML (n = 8), ALL (n = 5) and CLL (n = 9) were small, and the incidences of AMC were close to those found in the corresponding cell lines from healthy probands. In 39 patients with AML, the incidence of AMC was higher than in the other cell lines investigated. A positive skew distribution of AMC values and a positive significant correlation between incidence of AMC were found at the time of diagnosis and subsequent survival of the patients with AML, in spite of differences in treatment. It is suggested that this positive correlation may be due to an immune reaction of the patients against their tumour cells.
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PMID:Amoeboid movement configuration in tumour cells of bone marrow smears from patients with leukaemia. Incidence and significance. 26 78

Cellular recovery, maturation, and colony-forming cell (CFC) generation patterns of bone marrow cells from 23 patients with acute, subacute, and chronic myeloid leukemia (AML, SML, and CML) were studied using liquid and agar culture techniques. Increased recovery of proliferative myeloid cells from liquid culture was noted in 6 of 8 AML patients at diagnosis or relapse and 5 of 7 untreated SML patients. Patients with either AML or SML with rapid clinical progression exhibited greater recovery of cells in vitro with less maturation than patients with more stable disease. Studies from 3 patients with CML showed normal to increased cellular recovery with normal maturation. Three of 4 studies of AML patients followed sequentially in apparent remission, but with impending relapse, exhibited increased numbers of myeloblasts and promyelocytes, whereas 28 of 32 studies performed during stable remission were normal. The normally observed increase in CFC during liquid culture was absent in most leukemic marrow samples studied (3 of 4 AML, 4 of 6 SML, and 2 of 3 CML). Persistent low recovery of CFC during AML remission was associated in 3 patients with short remission duration. These studies indicated the potential utility of these techniques for the clinical evaluation of patients with myeloid leukemia and for studying factors involved in the progression of these diseases.
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PMID:Divergent patterns of marrow cell suspension culture growth in the myeloid leukemias: correlation of in vitro findings with clinical features. 26 54

Despite the incomparability in the reporting of leukemia and lymphoma incidence among populations and the relative rarity of these diseases, real differences in rates are discernible from available data. In general, the incidence of each of the leukemias and lymphomas is lower in Japan than in other Pacific rim populations whose rates are known. Particularly striking is the low incidence of CLL in Japan. Among Japanese in Hawaii, rates of some of these cancers (lymphosarcoma, CML) approach those of whites, whereas rates of other cancers (Hodgkin's disease, multiple myeloma, ALL, CLL, and AML) more closely resemble those of native Japanese. The number of Chinese living in countries served by population-based cancer reporting systems is too small for any firm conclusions to be made about leukemia and lymphoma incidence in this group. The incidence of these diseases in certain other nonwhite Pacific rim residents (i.e., Mexican Americans, blacks, and Maoris) is, by and large, similar to that of whites.
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PMID:Geographical variation in the incidence of the leukemias and lymphomas. 29 90

The membrane phenotype of leukaemic cells was analysed during different stages of chronic myeloid leukaemia by a panel of markers. These included antisera against ALL antigen, p23,30 (Ia-like structure) and other T cell, B cell and myeloid markers 'Lymphoid' blast crisis shares the phenotype of common ALL (of non-T, non-B variety). Both leukemias react with anti-ALL serum and have pre-myeloid, pre-B lymphoid and pre-thymocyte characteristics. Their phenotype may reflect the characteristics of the pluripotential stem cell from which they derive. Nevertheless both leukaemias retain their undifferentiated characteristics and lack overt myeloid, B cell and thymocyte differentiation markers. Myeloid blast crisis and AML are negative with anti-ALL serum but some of the poorly differentiated myeloblasts react with anti-p23,30 serum (and negative for SmIg). The anti-p23,30 serum (used in a double marker assay combined with anti-immunoglobulin) detects some (4-11%) intermediate sized agranular p23,30+/SmIg-cells in peripheral blood during the chronic phase of CML as well as in normal foetal bone marrow. These could be myeloid stem cells (from which in CML the myeloid blast crisis arises). The results demonstrate that surface membrane analysis can aid exact diagnosis in different stages of CML.
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PMID:Membrane marker analysis of 'lymphoid' and myeloid blast crisis in PH1 positive (chronic myeloid) leukemia. 30 6

Of particular interest in the study of cell membrane markers of leukemic cells were cytotoxic and immunofluorescent results obtained in comparing Ia alloantigen and complement receptor (CR) expression on normal leukocytic and leukemic cell types. Using discontinuous Ficoll gradients, Ia alloantigens were found on varying numbers of leukemic myelo- and lymphoblasts, and on the early stages of normal melocytes. Ia alloantigens, however, were not detectable on mature polymorphonuclear cells. This establishes human Ia alloantigens as cell surface differentiation markers. The appearance of complement receptors was observed later than that of Ia alloantigens. CR1 (EAC1-4b) showed up later in the differentiation than CR2 (EAC1-3d). Thus, an immunological discrimination between AML blasts and CML blast crisis blasts appears to be possible: AML blasts are mostly Ia-positive but CR-negative, whilst CML blast crisis cells are only 20-30% Ia-positive and carry complement receptors in at least equal amounts. The AML blast cell would appear as the less-differentiated cell type when compared to the CML blast crisis cells. The picture, however, remains complex since in CML blast crisis at least three different types of blast cells can be identified: an Ia-positive and an Ia-negative myeloid blast as well as an Ia-positive lymphoid blast. The quantitative composition of these three elements within the myeloid differentiation profile can vary somewhat from patient to patient. Furthermore, these studies revealed a disturbed differentiation of leukemic cell types.
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PMID:Classification of leukemic cells by Ia alloantigens and complement receptors. Surface probes for cell differentiation. 37 3

Five cases of Ph1-positive AML were studied. In all cases a Ph1-chromosome was shown with banding techniques to be due to a translocation between chromosomes No. 9 and No. 22. Cases 1 and 4 were found to have more than one Ph1 with evidence of only on Ph1-translocation accompanying other chromosome abnormalities. Two cases represented an unusual pattern of appearance and disappearance of the Ph1-positive clone during their clinical courses: Case No. 2 was originally Ph1-positive (46,XY,Ph1) but two months before his expiration the Ph1-positive clone was completely replaced by a newly developed Ph1-negative clone with an abnormal chromosome No. 21 (46,XY,21q+), whereas case No. 3, primarily Ph1-negative, developed a Ph1-positive clone among the previously karyotypically normal cells one month before death. The Ph1-positive AML cases presented have been discussed in relation to: 1) the genesis and significance of the Ph1-positive clone, 2) differentiation from the blastic phase of CML and 31 the general experience with Ph1-positive acute non-lymphocytic leukemia (ANLL), the world literature of which have been tabulated.
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PMID:Chromosomes and causation of human cancer and leukemia. XXXII. Unusual features of Ph1-positive acute myeloblastic leukemia (AML), including a review of the literature. 37 56

Thirteen leukemic patients with disease refractory to conventional chemotherapy were treated with 1.0 to 7.5 g/m2 of Cytosine Arabinoside (Ara-C) over 29 drug cycles. Drug infusions were spaced at 12-hour intervals; a maximum of four doses was administered over 36 hours. After single dose tolerance had been established, three or four dose cycles were given at 2- to 30-day intervals. There were three partial remissions (PR) and one complete remission (CR) in a treatment group of four patients with AML, five with ALL, two with lymphoma converted to leukemic phase, one CML in blast crisis, and one promyelocytic leukemia. Five of the patients were septic and considered terminally ill at the time of treatment. All other patients had evidence of drug responsiveness. The nadir of the white count occurred from 3 to 12 days after treatment, with subsequent recovery of the peripheral granulocyte count between days 12 and 28. Toxicity included nausea and vomiting (GI symptoms) in twelve patients, central nervous system (CNS) disturbances in eight patients, one episode of inappropriate antidiuretic hormone syndromes (SIADH), one of hyperuricemia, and fever in eleven patients. There was no evidence of hepatic or renal dysfunction. These high doses of Ara-C appear useful for treatment of patients with refractory leukemia. Hospitalization is brief and toxicity acceptable.
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PMID:High dose cytosine arabinoside (HDARAC) in refractory acute leukemia. 49 9

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