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Query: UMLS:C0002874 (
aplastic anemia
)
5,905
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Iron overload is found clinically in such conditions as hemochromatosis and sideroblastic anemia, and after long term repeated transfusion in
aplastic anemia
. An animal model of iron overload was successfully developed in rats and rabbits by repeated intraperitoneal injections of ferric nitrilotriacetate (Fe3+-NTA). This procedure induced a diabetic state with hyperglycemia, ketonemia, glycosuria and ketonuria. Blood venesection on these rats reduced the iron load in the liver and pancreas, and ameliorated the general diabetic symptoms. A single injection of Fe3+-NTA in rats induced a temporary elevation in plasma iron concentration, lipid peroxidation in the perfused liver homogenate expressed by malondialdehyde (MDA) formation, blood GOT, GPT, ALP and gamma-GTP sequentially. Fe3+-NTA uptake in the liver caused membrane lipid peroxidation, and subsequently produced a transit liberation of liver cell enzymes, although the incorporated liver Fe3+-NTA was only 1% of the injected dosage (7.5 mg iron/kg BW) at 3 hr after injection. The direct toxic effect of Fe3+-NTA to living cells was examined using cultured normal rat liver parenchymal cells (RL-34). Marked cytolysis was found in cells exposed to more than 25 micrograms of iron through Fe3+-NTA/ml. At 50 micrograms iron of Fe3+-NTA/ml, most cells were lethally injured and the remaining cells were piled up and aggregated at 15 days. They grew on soft agar culture, and when inoculated subcutaneously to five newly born rats a subcutaneous tumor developed in all animals within three weeks. Lung metastases were found in three of five inoculated rats. A spin trapping technique with electron spin resonance (ESR) on Fe3+-NTA employing 5, 5-dimethyl-l-pyrroline-N-oxide (DMPO) yielded a spin adduct with three doublets (DMPO-Z) which corresponded to singlet oxygen. By ESR in the presence of
H2O2
, the Fe3+-NTA solution strongly generated hydroxyl radical. The production of active oxygen species by Fe3+-NTA solution may explain the toxicity and carcinogenicity of Fe3+-NTA. The majority of stainable iron in the iron overloaded tissue was hemosiderin (Hs). We tried to purify the Hs from multi-transfused human spleen by the method of Weir et al. The purified Hs did not show a DMPO-OH adducts in the presence of
H2O2
and DMPO on ESR measurement. The Hs iron was solubilized with several biological ligands in an acidic state in the presence of a reducing reagent like glutathione. Solubilized Hs iron produced iron chelate complexes which resulted in OH radicals production in the presence of
H2O2
in acidic conditions below pH 5.5.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:[Pathogenesis and mechanism of iron overload: ferric nitrilotriacetate, hemosiderin, active oxygen, and carcinogenesis]. 268 76
Reduction of the nitro group of chloramphenicol (CAP) gives rise to more highly reactive intermediates which may in involved in the
aplastic anemia
associated with CAP use. One such intermediate, nitroso-chloramphenicol (NO-CAP), has been found to be a potent agent for mediating degradation of isolated DNA. In a reaction mixture containing 100 microM NO-CAP, 100 microM CuCl2, and 5 mM NADH, 7 micrograms of Escherichia coli [3H]DNA was completely degraded to acid-soluble fragments in 30 min. Damage to DNA was in the form of single-stranded scissions. The requirement for copper was specific, and copper chelating reagents blocked the degradation. The need for a reducing agent could be met equally well by NADH or NADPH, but not by sulfhydryl reagents such as glutathione, dithiothreitol and 2-mercaptoethanol. Oxygen was also necessary for the NO-CAP mediated DNA damage, with reduced forms of oxygen participating in the reaction. A role for
H2O2
was indicated by the inhibition of the degradation seen when catalase was included in the mixture. Hydroxyl radicals are known to be produced in the reaction of
H2O2
with certain transition metals. Scavangers of hydroxyl radicals also inhibited strand-scission, suggesting that the radicals may be the primary agents in DNA degradation. The importance of the nitroso moiety of NO-CAP was evidenced by the lack of DNA damage seen when NO-CAP was replaced by CAP under the conditions tested.
...
PMID:Degradation of isolated deoxyribonucleic acid mediated by nitroso-chloramphenicol. Possible role in chloramphenicol-induced aplastic anemia. 712 41
We analyzed active oxygen (hydroperoxide;
H2O2
) production by peripheral neutrophils in various hematological diseases by flow cytometry. One hundred microliters of heparinized fresh blood was sequentially incubated at 37 degrees C with 2',7'-dichlorofluorescein diacetate and with or without phorbol myristate acetate (PMA). After hemolysis, the pelleted white blood cells were subjected to flow cytometry, and the neutrophil fraction was gated on the cytogram. Production of
H2O2
by the fraction was estimated by determining the increase in the relative intensity of fluorescence emitted from the fraction in response to stimulation by PMA. In controlled chronic myelogenous leukemia (CML) (WBC < 1 x 10(10)/1),
H2O2
production was normal, while in uncontrolled CML (WBC > or = 1 x 10(10)/1), it was reduced. In myelodysplastic syndrome (MDS),
H2O2
production was also reduced, but no significant difference was observed among FAB classification disease types in MDS patients. In untreated acute non-lymphocytic leukemia (ANLL),
H2O2
production was reduced, while in the complete remission stage of ANLL, its level was normal, suggesting recovery from normal clones. In
aplastic anemia
, the
H2O2
production level was normal. Steroid therapy might be responsible for the reduction of
H2O2
production in non-Hodgkin's lymphoma and multiple myeloma. The production of
H2O2
is closely related to the oxygen-dependent bactericidal activity of neutrophils, and, hence, can be utilized as an index to indicate susceptibility to infection. This neutrophil function can be determined easily in ordinary clinical facilities by using flow cytometry, and care should be taken to prevent infection when
H2O2
production is reduced.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Flow cytometric determination of active oxygen (hydroperoxide) produced by peripheral blood neutrophils in patients with hematological disorders. 836 85
Exposure of humans and experimental animals to benzene has been shown to result in hematotoxicity such as pancytopenia,
aplastic anemia
, and leukemia. The oxidative activation of the benzene metabolite, hydroquinone (HQ), in the bone marrow to the electrophilic benzoquinone (BQ) has been suggested to play an important role in benzene-induced hematotoxicity. Since the interaction of several xenobiotics with copper has been shown to result in their metabolism, in this study we have investigated the role of copper in the oxidation of HQ and HQ-induced toxicity to mice bone marrow stromal cells, target cells of HQ in the bone marrow. In phosphate-buffered saline, HQ underwent autoxidation slowly to BQ, while the presence of Cu(II) ions (1, 2.5, 5, 10, 50 microM) strongly accelerated the oxidation of HQ to BQ in a concentration-dependent manner. Reaction of HQ with Cu(II) was also accompanied by the reduction of Cu(II) to Cu(I), the utilization of O2, and the concomitant generation of
H2O2
. The oxidation of HQ by Cu(II) could be blocked by the Cu(I)-specific chelator bathocuproinedisulfonic acid (BCS), particularly when the ratio of BCS to Cu(II) was 4:1. By observing the kinetics of the reactions derived from mixing 100 microM HQ and 100 microM Cu(II), it was found that all of the Cu(II) was reduced to Cu(I) within 5 s, followed by consumption of O2 and the generation of BQ, which reached maximum levels at 4 min after mixing HQ and Cu(II). In addition, oxidation of HQ by Cu(II) also generated chemiluminescence. In the presence of myeloperoxidase, Cu(II)-mediated oxidation of HQ was increased. Addition of Cu(II) to primary bone marrow stromal cell cultures significantly enhanced HQ-induced cytotoxicity. The enhanced cytotoxicity of HQ by Cu(II) could be completely prevented by adding BCS, glutathione (GSH), or dithiothreitol but not by catalase. Supplementation of stromal cells with 20 microM BCS in the absence of exogenously added Cu(II) significantly abated HQ-induced cellular GSH depletion and cytotoxicity, suggesting a possible involvement of endogenous copper in the activation of HQ. The above results indicate that Cu(II) strongly induces the oxidation of HQ and as such may be a factor involved in the oxidative activation and toxicity of HQ in target cells.
...
PMID:Oxidation of hydroquinone by copper: chemical mechanism and biological effects. 842 68
Some compounds having thionamide structure inhibit thyroid functions. Such antithyroid thionamides include mercaptomethylimidazole (methimazole), thiourea and propylthiouracil, of which mercaptomethylimidazole is widely used to treat hyperthyroidism. Undesirable side effects develop from these drugs due to extrathyroidal actions. Antithyroid thionamides inhibit lactoperoxidase which contributes to the antibacterial activities of a number of mammalian exocrine gland secretions that protect a variety of mucosal surfaces. These drugs stimulate both gastric acid and pepsinogen secretions, thereby augmenting the severity of gastric ulcers and preventing wound healing. Increased gastric acid secretion is partially due to the H2 receptor activation, and also through the stimulation of the parietal cell by intracellular generation of
H2O2
following inactivation of the gastric peroxidase-catalase system. Severe abnormalities may develop in blood cells and the immune system after thionamide therapy. It causes agranulocytosis,
aplastic anemia
, and purpura along with immune suppression. Olfactory and auditory systems are also affected by these drugs. Thionamide affects the sense of smell and taste and also causes loss of hearing. It binds to the Bowman's glands in the olfactory mucosa and causes extensive lesion in the olfactory mucosa. Thionamides also affect gene expression and modulate the functions of some cell types. A brief account of the chemistry and metabolism of antithyroid thionamides, along with their biological actions are presented.
...
PMID:Extrathyroidal actions of antithyroid thionamides. 1186 23
