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Query: UNIPROT:P02794 (ferritin)
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What then are the lessons to be learned about prevention and treatment of hemochromatosis? Early diagnosis is essential. The best indicator would be testing of serum iron and total saturation followed by a serum ferritin if elevated. Once these indices are abnormally high, MRI and or a liver biopsy should confirm the stage of the iron over-loaded state. If indeed the patient is not iron-overloaded (normal liver biopsy in the face of high saturation and ferritin level) phlebotomies should be performed until these indices are normal and then maintained at a normal level. This should entail four to six phlebotomies a year. Family members should also be screened and managed in a like manner. HLA typing may be a partially helpful screening device. The abnormal gene is closely linked on chromosome 6 with HLA histocompatibility loci. Now, by means of HLA typing, we can identify heterozygote carriers and homozygous (abnormal) among first degree relatives of patients with hemochromatosis. Unfortunately, HLA typing can only be used within a given family and cannot be used to screen the general population. It is estimated that 70% of hemochromatoics have the antigen HLA-A3; however, so does 28% of the (well) general population. Patients with unexplained cirrhosis, arthritis, liver disease, diabetes, impotency, cardiomyopathy and neurological symptoms should be screened in a like manner. Routine health practice profile chemistries must include a serum iron and iron saturation, and if high followed by a serum ferritin. Once diagnosed, therapy must be maintained with phlebotomy for the life time of the patient.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Hemochromatosis: diagnosis and treatment. 179 61

Hereditary haemochromatosis is an autosomal recessive disease that is genetically expressed by excessive accumulation of iron in the tissues, resulting in cirrhosis, diabetes mellitus, cardiomyopathy and hypogonadism. As the disease may be diagnosed before the appearance of symptoms, and prevented by repeated phlebotomies, there are strong implications for adoption of a screening procedure. Determinations of transferrin saturation (TS) and serum ferritin concentration (SF) were used to screen 4302 blood donors, who were selected for follow-up studies if they fulfilled any of the following three criteria: (i) TS greater than or equal to 0.7; (ii) TS greater than or equal to 0.5 together with SF greater than or equal to 150 micrograms l-1; (iii) SF greater than or equal to 300 micrograms l-1. A total of 58 subjects who fulfilled at least one of these criteria were reinvestigated, after which 18 individuals still fulfilled at least one criterion. Fifteen subjects having SF greater than or equal to 300 micrograms l-1 were offered liver biopsy and thirteen of these accepted. In one individual, no stainable iron was detected, and two subjects did not fulfil the previously established diagnostic criteria for the diagnosis of hereditary haemochromatosis. Ten subjects who had a high TS and liver iron grade 2-4 according to Bassett were classified accordingly as homozygotes. On the basis of these results, the prevalence of haemochromatosis in Denmark was estimated to be 0.0037-0.0046.
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PMID:Screening for haemochromatosis: prevalence among Danish blood donors. 189 49

The possibility of a metabolic chronic liver disease must always be borne in mind since in certain cases treatment can prevent the lesions from getting worse. The clinical and biochemical context should suggest either (1) genetic haemochromatosis when faced with high serum iron and ferritin levels and elevated transferrin saturation or with a suggestive clinical context (melanoderma, diabetes, hypogonadism, arthropathy, myocardiopathy); or (2) Wilson's disease in young subjects, especially in the presence of neurological and ocular signs or of haemolytic anaemia; or (3) porphyria in case of cutaneous manifestations caused by exposure to sun light. Hence the importance of full clinical examination in patients with chronic liver disease.
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PMID:[Metabolic cirrhosis (hemochromatosis, Wilson's disease, erythropoietic protoporphyria)]. 206 17

The use of the extremely effective anthracycline antitumor drugs adriamycin and daunomycin is limited by a severe, dose-dependent cardiomyopathy. Anthracycline-induced toxicity has been proposed to involve iron-dependent oxidative damage to biological macromolecules yet little is known regarding the availability of physiologic iron. We now report that, in the presence of NADPH-cytochrome P-450 reductase, these drugs undergo redox cycling to generate superoxide which mediates a slow, reductive release of iron from ferritin, the major intracellular iron storage protein. Anaerobically, the semiquinone free radical forms of adriamycin and daunomycin catalyze a very rapid, extensive release of iron from ferritin. In contrast, diaziquone, an aziridinyl quinone antitumorigenic agent which is less cardiotoxic, is unable to release iron from ferritin. Thus, the present studies suggest that the cardiomyopathy observed with the anthracyclines, and perhaps their antineoplastic activity as well, may be related to their ability to delocalize tissue iron, thereby contributing to the formation of strong oxidants capable of damaging critical cellular constituents.
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PMID:Release of iron from ferritin by cardiotoxic anthracycline antibiotics. 301 16

Acquired hemosiderosis resulting from massive iron deposits in various organs, including heart, liver, and pancreas, may lead to architectural and functional disturbances of these organs. Even though iron overload can occur in nonuremic as well as in uremic individuals, the dialysis patient is at particular risk for developing hemosiderosis. Many dialysis patients receive exogenous iron from either oral iron therapy or blood transfusions. In addition, these patients seem to be at high risk for retaining iron. A diagnosis of excess iron deposition should be considered if the patient has unexplained cardiomyopathy, hepatic cirrhosis, proximal myopathy, diabetes mellitus, arthropathy, or immune dysfunction such as listeriosis. Several techniques are available for determining iron overload. Diagnostic tests include measuring serum ferritin levels, staining bone marrow preparations for excess iron, measuring tissue hemosiderin concentrations, magnetic resonance imaging, and the deferoxamine (DFO; Desferal) "challenge test." The simplest treatment for iron overload in nonuremic patients is removal of iron by venesection. However, in patients in whom venesection is not feasible, the chelating agent DFO can effectively remove excess iron. In the dialysis patient, DFO therapy can be combined with either dialysis or hemoperfusion to remove the iron-DFO complex that would otherwise be removed by the kidney. DFO therapy in the nondialyzed individual has proven to be successful, but before treatment, the benefits of the treatment must be weighed against possible adverse side effects such as cataracts, changes in color vision, and anaphylaxis. In the dialysis patient, indications for iron removal are less clearly defined.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Management of iron overload in dialysis patients. 329 89

In RDT hemosiderosis appears to be an inevitable complication only in the small number of patients in need of frequent transfusions. To prevent clinical consequences (e.g. cardiomyopathy) known from polytransfused patients without renal disease, transplantation should be considered in RDT patients in need of frequent transfusions. Iron substitution - preferably oral - to replace dialysis-related iron loss does not cause clinically significant hemosiderosis provided iron stores are monitored adequately. A sufficient method of controlling iron stores in RDT patients under iron substitution or regular transfusion therapy is a twice annual determination of serum ferritin concentration. The treatment of choice for hemosiderosis in nontransfused RDT patients is discontinuation of iron substitution. When polytransfused RDT patients with severe hemosiderosis cannot be transplanted and submitted consecutively to phlebotomy, DFO treatment is indicated. Quantitative data regarding optimal dosage and application of DFO in RDT patients are not yet available. Constant infusion of DFO during hemodialysis may be superior to bolus application.
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PMID:Therapy and monitoring of hypersiderosis in chronic renal insufficiency. 671 93

We describe a 10-year-old girl with familial haemochromatosis which is associated with a normal concentration of S-ferritin, myocardial disease and diabetes mellitus. We speculate that iron is accumulated primarily in the heart and pancreas as such isoferritins are not detected by the routine assay of serum ferritin based on antispleen or placenta ferritin. Further, this condition is compared with lysinuric protein intolerance, an inborn error of diamino-acid transport where an opposite discrepancy between S-ferritin and storage iron is seen.
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PMID:Why concentration of serum ferritin does not in all circumstances reflect storage iron but is still of value in its estimation. 686 6

Primary hemochromatosis is characterized by a specific pattern of clinical manifestations. It includes liver disease with hepatomegaly, glucose intolerance, e.g. diabetes, hyperpigmentation oft the skin, impotence/ amenorrhea, arthropathy, cardiomyopathy and fatigue. Laboratory investigation reveals significantly elevated serum ferritin and transferrin saturation with iron. The diagnosis is confirmed by liver biopsy and quantitative determination of elevated liver iron content. Wilson's disease represents a copper storage disease. Prominent clinical features are hepatomegaly and splenomegaly. Neurological alterations and detection of Kayser-Fleischer corneal rings are typical. In the acute initial phase the often young patients present with Coombs-negative hemolysis. Psychiatric alterations, cardiomyopathy, arthropathy, nephropathy, as well as thrombocytopenia and leucopenia are other clinical features. Laboratory parameters of Wilson's disease include low serum ceruloplasmin and serum copper. There is an elevated urinary copper excretion and elevated serum free copper concentration. The diagnosis is confirmed by liver biopsy with quantitative determination of an elevated liver copper content.
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PMID:[Current diagnosis: hereditary metabolic diseases of the liver (primary hemochromatosis, Wilson disease)]. 898 78

Hereditary hemochromatosis (HHC) is an inherited disease transmitted in an autosomal recessive pattern. With homozygosity occurring in up to 0.5% of the population, HHC is the most prevalent genetic disease among the white population worldwide and has the same prevalence as the sickle cell trait in the African-American population. An asymptomatic 50-year-old white man presented at the family practice clinic and stated that HHC had been diagnosed in his mother. Laboratory findings showed markedly elevated transferrin saturation and ferritin levels. The diagnosis of HHC was made on the basis of the laboratory results and family history, and therapy was begun. Clinical manifestations of HHC occur late and include diabetes mellitus, cirrhosis, and cardiomyopathy. As end-organ damage is preventable, optimal management involves early diagnosis and lifelong phlebotomy. Diagnosis is made by an elevated transferrin saturation level and an increased serum ferritin value. Hereditary hemochromatosis is a genetic disorder of iron metabolism that has an excellent prognosis if diagnosed early.
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PMID:Hereditary hemochromatosis. 907 Dec 52

Desferrioxamine (DFX) remains the most effective and safe iron chelator for treatment of patients with transfusional iron overload. It is usually given by intermittent subcutaneous infusions for 8-12 h on 4-6 days weekly using a battery-driven pump. Disposable balloon infusers provide a suitable method of giving continuous subcutaneous infusions with improved patient compliance. For patients with cardiac abnormalities due to iron overload, continuous intravenous desferrioxamine is essential to eliminate toxic plasma non-transferrin bound iron and to reduce body iron stores. Deferiprone (L1, l-2 dimethyl-3hydroxy-pyrid-4-one) is a less effective iron chelator but has the advantage of being orally active. Long-term trials in which patients have taken 75 mg/kg/day have shown that deferiprone is capable of maintaining body iron stores at safe levels in a proportion of thalassaemia major patients but body iron stores, assessed by liver biopsy remain at high levels (> 15.0 mg/g dry weight) in a substantial number of patients. These concentrations have been associated with tissue damage. Trials of increased doses of deferiprone (up to 100 mg/kg/day) or of combined therapy with daily deferiprone and DFX or 1 or 2 days each week are being carried out in an attempt to achieve lower body iron burden in these patients. Preliminary results show that the drugs can be given safely together and urine iron excretion produced is additive, implying that the drugs chelate different body iron pools. Patients previously well chelated with serum ferritin levels less than 2500 micrograms/L have the fewest side-effects from deferiprone and usually may be kept at the same level of body iron for periods of at least 4 years, assessed by serum ferritin and urine iron excretion. The side-effects of deferiprone result in some patients discontinuing therapy. These side-effects, especially arthropathy, mainly occur in previously poorly chelated and so the most heavily iron-loaded patients. Nausea and other gastrointestinal symptoms, agranulocytosis or milder degrees of neutropenia account with arthropathy for nearly all the withdrawals from deferiprone therapy. Patients with cardiomyopathy due to iron overload should be given intravenous DFX rather than deferiprone. Deferiprone, licensed for pharmaceutical use in India, awaits official approval for widespread clinical use in Western Europe and North America. Meanwhile, attempts to find new orally active iron chelators and improved methods of administration of desferrioxamine are in progress.
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PMID:Iron chelation therapy. 935 Jan 80

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