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Query: UMLS:C0240066 (iron deficiency)
 7,156 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Iron-deficient female Wistar rats were fed a diet, which contained 0.5% trimethylhexanoylferrocene, over a 56-week period. This dietary iron loading resulted in a progressive siderosis and enlargement of the liver with a maximum iron content of 947.0 +/- 148.0 mg (vs. 0.07 +/- 0.04 mg in iron deficiency) and a maximum organ weight of 39.4 +/- 6.6 g (vs. 6.9 +/- 1.4 g in iron-deficient control rats). Up to 43 weeks, whole liver iron rose by increase in iron concentration (max. 28.0 +/- 6.1 mg/g wet weight, w.w.) as well as by enlargement of the organ. Afterwards whole liver iron increased solely by ongoing hepatomegaly. At the commencement of iron loading, stainable iron was almost exclusively stored by hepatocytes equally throughout all areas of the liver lobule. Later, the distribution of iron-loaded hepatocytes became strikingly periportal, and, in addition, Kupffer cells as well as sinus-lining endothelia began to store iron. Animals with a liver iron concentration of more than 10.4 +/- 0.75 mg/g w.w. showed no further increase in ferritin and haemosiderin within hepatocytes. Iron-burdened Kupffer cells/macrophages, however, accumulated permanently, hereby forming intrasinusoidal and portal siderotic nodules and areas. First signs of liver damage such as necrosis of single hepatocytes and mild fibrosis began at a liver iron concentration of 14.7 +/- 1.4 mg/g w.w. With advancement of iron loading, focal necrosis of hepatocytes and iron-burdened macrophages took place, and significant perisinusoidal as well as portal fibrosis developed. Cirrhosis, however, the final stage of impairment in iron overload of the liver in humans, could not be induced in this animal model up to now.
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PMID:Iron overload of the liver by trimethylhexanoylferrocene in rats. 159 22

The light and electronmicroscopic representation of non-haemiron in the bone-marrow provides the unique opportunity of extensively evaluating the iron metabolism. In the bone-marrow, macrophages represent the physiological place of iron storage. The iron in the cytoplasma is stored in them in the form of free ferritin molecules and lysomally as aggregated ferritin and/or haemosiderin in siderosomes. In an equal iron balance and unimpaired internal iron exchange only erythroblasts (sideroblasts) and erythrocytes (siderocytes) of the bone-marrow besides macrophages possess siderosomes. In addition to this physiological or orthotopic iron storage a heterotopic iron storage can be observed under pathological conditions, particularly with iron overloading of the organism, in the endothelial cells of sinusoids and plasma cells. In detail, the patterns of iron storage in the bone-marrow are described in the different stages of iron deficiency, disturbance of iron utilization in chronically inflammatory processes or tumour diseases, condition after intravenous iron administration, transfusion siderosis, hereditary haemochromatosis and sideroblastic anaemia.
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PMID:The diagnostic value of bone marrow iron. 170 12

In the bone-marrow, non-haemoglobin iron can predominantly be found in the reticulum. Slight granules containing iron can also be observed in parts of erythroblasts by means of the Berlin blue reaction. These cells are called sideroblasts. In chemical respect, non-haemoglobin iron consists of ferritin soluble in water and haemosiderin insoluble in water. Erythroblasts will only take their iron from plasma transferrin. For the most part, this iron uptake is being regulated by erythropoietin adapting erythropoiesis to the oxygen requirements of the tissue. The iron contained in erythroblasts is predominantly utilized for haemoglobin synthesis in these cells. A slight part is being taken up by ferritin. The bone-marrow reticulum will phagocytise aged erythrocytes and store liberated iron as ferritin and haemosiderin. Part of the iron is being delivered again to plasma transferrin. With constant serum iron level the liberation of iron from the reticulo-endothelial tissue must correspond to the iron uptake by erythropoiesis. The absence of iron capable of being coloured in the bone-marrow reticulum is considered to be a reliable parameter of iron deficiency. It enables the diagnosis of iron deficiency anaemia to be made even in those patients with serum iron level and a total iron binding capacity lying within the normal range and no hypochromia of erythrocytes being present. It enables iron deficiency anaemia to be separated from sideropenic anaemia with reticulo-endothelial siderosis in differential-diagnostic manner. Even in patients with sideroblastic anaemia, iron colouring of bone-marrow smears is required for ensuring the diagnosis. Recently, a separation has also been made for idiopathic anaemia with abnormal sideroblasts. In these patients there is an increased risk for acute leukemia to develop.
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PMID:[Iron in bone marrow]. 618 56

The nature of iron in the serum of patients with idiopathic hemochromatosis has been studied utilizing an isotope labeling method and results have been compared with those from normal individuals and patients with other forms of liver disease. Between 2 and 4% of a tracer dose of 59Fe added to normal serum was retained by DEAE Sephadex and has been designated non-transferrin-bound. Alcoholic liver disease, chronic active hepatitis, and iron deficiency have no effect on this fraction. In idiopathic hemochromatosis 34.6 +/- 3.9% of the added iron was not bound to transferrin at diagnosis, representing approximately 700 microgram Fe/liter serum. Treatment lowers this fraction before serum iron concentration falls to normal. The majority of the non-transferrin-bound iron is of low molecular weight and is not bound to albumin. The presence of this fraction may contribute significantly to the development of tissue siderosis.
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PMID:A non-transferrin-bound serum iron in idiopathic hemochromatosis. 737 72

Female Wistar rats with slight iron deficiency anemia were kept on a diet containing 0.5% trimethylhexanoyl (TMH)-ferrocene for up to 79 weeks. In the state of iron deficiency, the heart was free of light-microscopically detectable iron. After 7 weeks of the TMH-ferrocene diet, the first iron-positive granules appeared in perivascular macrophages. Further oral administration caused a progression of iron deposition in these cells, visible in the form of a granular staining but also as a diffuse iron staining of the cytoplasm. Accordingly, at the electron-microscopical level, the iron was stored partly as free ferritin molecules in the cytosol, and partly in lysosomes in the form of ferritin and/or hemosiderin. After 11 weeks, further iron-positive cells with relatively small dark-blue granules were found in the vicinity of capillaries, which could be identified as fibrocytes by means of electron microscopy. In addition, slight iron deposition occurred in the endothelial cells of the cardiac capillaries, likewise mainly in the form of small, uniform siderosomes. The myocytes showed no product of Perls' Prussian blue reaction during the whole period of investigation. From the 11th week onwards, discrete ferritin molecules were detected electron microscopically within lysosomes of these cells. Their amount increased slowly with progression of the TMH-ferrocene feeding period. Free ferritin molecules could be observed in the cytosol of fibrocytes, endothelial cells and myocytes in only very slight concentrations, whilst they were more plentiful in macrophages. In hereditary hemochromatosis and posttransfusional siderosis, the iron is found predominantly in myocytes and appears to cause cell damage, whilst this is not the case in experimental iron overload in rats.
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PMID:Pattern of iron storage in the rat heart following iron overloading with trimethylhexanoyl-ferrocene. 797 87

Iron deficiency affects approx. 20% of the world population. Due to predominantly vegetarian diets that reduce the bioavailability of food iron drastically, deficiency states are most widely distributed in developing countries. In addition, iron demand is increased by blood losses and by fast growth which increases the risk of iron deficiency in infants, young adolescents, and in menstruating and pregnant women. The symptoms of iron deficiency include impaired physical and intellectual performance. Iron supplementation may help to break the vicious cycle between inadequate nutrition and poverty. Fortification programs have to consider social and health aspects, including provision against iron overload. Excess iron stores may promote cancer and increase the cardiovascular risk, though the latter is a subject of current debate. The best approach to control such risks is individual iron supplementation geared to the demand by adequate laboratory controls. However, this approach is too costly for general application in developing countries. Food-iron fortification has successfully reduced iron deficiency in many trials and, in comparison, is much cheaper. As iron deficiency is widely distributed in most developing countries, the risk of inducing iron overload in the general population is low. Genetically determined diseases that may lead to siderosis, such as hereditary haemochromatosis or thalassaemia major, show a limited geographic and ethnic distribution. Such subgroups can be largely avoided by targeting food-iron fortification to infants, young adolescents, or pregnant women. Food vehicle and iron compound have to be matched in order to optimise iron bioavailability and to avoid rancidity in food, spoiling its taste and odour. The fortification of salt, sugar and spice mixtures or of bakery products with a short shelf-life are valid approaches to this end. Alternatively, haem iron can be used to fortify cereal-based food staples in developing countries such as tortillas or chappaties. Thus, a variety of options is available to solve the technical problems of food iron fortification. However, optimal solutions have to be tailored to the individual situation in each country.
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PMID:Iron supplementation. 985 25

Hereditary sideroblastic anemia is a very rare disease recessive and X-linked that affect heme biosynthesis by deficit or decreased of delta aminolevulinic acid synthase (ALAS) activity. We report a case of a six-month-old boy, admitted in the hospital for anemic syndrome. The hemogram showed anemia (hemoglobin: 4.5 g/dL), frankly hypochronic microcytic and a regenerated (mean corpuscular hemoglobin concentration: 26 g/dL, mean cell volume: 53 fl, reticulocytes: 10 x 10(9)/L) with red cells morphologic disorders in smears (anisopoikylocytosis) without attack of the other lineages; white blood cells: 11 x 10(9)/L (neutrophils: 64% and lymphocytes: 35%); platelets: 350 x 10(9)/L. Examination of bone marrow showed an important erythroid hyperplasia (about 69%) with dyserythropoiesis. Perls stain revealed intense siderosis with 90% of ringed sideroblasts and a large number of siderocytes. Exploration of ALAS2 and ABC7 genes on the DNA of the infant was not found abnormalities. Treatment with pyridoxine corrects moderately the anemia. By the way, we proposed to remind that iron deficiency, inflammatory syndrome and thalassemia are the common microcytic anemia. However, it's mandatory to explore other causes if diagnosis is not solved.
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PMID:[Hereditary sideroblastic anemia: a rare diagnosis]. 1521 71

In healthy subjects, the rate of dietary iron absorption, as well as the amount and distribution of body iron are tightly controlled by hepcidin, the iron regulatory hormone. Disruption of systemic iron homeostasis leads to pathological conditions, ranging from anemias caused by iron deficiency or defective iron traffic, to iron overload (hemochromatosis). Other iron-related disorders are caused by misregulation of cellular iron metabolism, which results in local accumulation of the metal in mitochondria. Brain iron overload is observed in neurodegenerative disorders. Secondary hemochromatosis develops as a complication of another disease. For example, repeated blood transfusions, a standard treatment of various anemias characterized by ineffective erythropoiesis, promote transfusional siderosis, while chronic liver diseases are often associated with mild to moderate secondary iron overload. In this critical review, we discuss pathophysiological and clinical aspects of all types of iron metabolism disorders (265 references).
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PMID:Disorders associated with systemic or local iron overload: from pathophysiology to clinical practice. 2190 Dec 9

Knowledge of the basic mechanisms involved in iron metabolism has increased greatly in recent years, improving our ability to deal with the huge global public health problems of iron deficiency and overload. Several million people worldwide suffer iron overload with serious clinical implications. Iron overload has many different causes, both genetic and environmental. The two most common iron overload disorders are hereditary haemochromatosis and transfusional siderosis, which occurs in thalassaemias and other refractory anaemias. The two most important treatment options for iron overload are phlebotomy and chelation. Phlebotomy is the initial treatment of choice in haemochromatosis, while chelation is a mainstay in the treatment of transfusional siderosis. The classical iron chelator is deferoxamine (Desferal), but due to poor gastrointestinal absorption it has to be administered intravenously or subcutaneously, mostly on a daily basis. Thus, there is an obvious need to find and develop new effective iron chelators for oral use. In later years, particularly two such oral iron chelators have shown promise and have been approved for clinical use, namely deferiprone (Ferriprox) and deferasirox (Exjade). Combined subcutaneous (deferoxamine) and oral (deferiprone) treatment seems to hold particular promise.
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PMID:Iron mobilization using chelation and phlebotomy. 2256 13

Heavy metals and trace elements play an important role in relation to the physiology and pathology of the nervous system. Neurologic diseases related to disorders of metabolism of copper and iron are reviewed. Copper disorders are divided into two classes: ATP7A- or ATP7B-related inherited copper transport disorders (Menkes disease, occipital horn syndrome, ATP7A-related distal motor neuropathy, and Wilson disease) and acquired diseases associated with copper deficiency or copper excess. Iron brain disorders are divided into genetic neurodegeneration with brain iron accumulation (NBIA, neuroferritinopathy, and aceruloplasminemia), genetic systemic iron accumulation with neurologic features (hemochromatosis), and acquired diseases associated with iron excess (superficial siderosis) or iron deficiency (restless leg syndrome). The main features of cadmium, lead, aluminum, mercury, and manganese toxicity are summarized.
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PMID:Disorders of heavy metals. 2436 57


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