Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0039730 (thalassemia)
10,305 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Liver iron measurements using biosusceptometers have been validated on two low-TC SQUID (Superconducting Quantum Interference Device) systems (New York and Hamburg) built in the 1980's. Recently, two new instruments have been installed in Torino, Italy (2001), and Oakland, California (2003). The design of the Oakland system is similar to those in Hamburg and Torino. Improvements were made to adjust for significant environmental noise, moreover, an active electronic noise cancellation, a computer controlled water coupling reference system using a pressure feedback and a faster data acquisition system using software lockin amplifiers have been implemented. All 3 systems (Hamburg, Torino, Oakland) are using the same standardized operational protocol. Presented herein are the data collected from 276 patients measured with the SQUID biosusceptometer at Oakland since installation. The results from 149 patients with beta-thalassemia (beta-Thal, age: 2-66 y), 76 patients with sickle-cell disease (SCD, age: 5-55 y), 35 patients with various rare diseases (RD, age: 2-80 y), and 16 patients with hereditary hemochromatosis (HHC, age: 6-74 y) are reported. The liver iron concentration in the different groups are 222 - 7570 (beta-Thal), 518 - 7918 (SCD), 511 - 6234 (RD), 258 - 2041 (HHC) microg/g-liver (in vivo wet weight). The long-term reproducibility (12 months) in a patient on constant treatment regimen demonstrated a mean liver iron of 1141 +/- 133 microg/g-liver. The new SQUID Ferritometer located on the US West coast will give more patients access to this non-invasive liver iron assessment.
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PMID:The new SQUID biosusceptometer at Oakland: first year of experience. 1601

Iron imbalance/accumulation has been implicated in oxidative injury associated with many degenerative diseases such as hereditary hemochromatosis, beta-thalassemia, and Friedreich's ataxia. Mitochondria are particularly sensitive to iron-induced oxidative stress - high loads of iron cause extensive lipid peroxidation and membrane permeabilization in isolated mitochondria. Here we detected and characterized mitochondrial DNA damage in isolated rat liver mitochondria exposed to a Fe2+-citrate complex, a small molecular weight complex. Intense DNA fragmentation was induced after the incubation of mitochondria with the iron complex. The detection of 3' phosphoglycolate ends at the mtDNA strand breaks by a 32P-postlabeling assay, suggested the involvement of hydroxyl radical in the DNA fragmentation induced by Fe2+-citrate. Increased levels of 8-oxo-7,8-dihydro-2'-deoxyguanosine also suggested that Fe2+-citrate-induced oxidative stress causes mitochondrial DNA damage. In conclusion, our results show that iron-mediated lipid peroxidation was associated with intense mtDNA damage derived from the direct attack of reactive oxygen species.
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PMID:Mitochondrial DNA damage associated with lipid peroxidation of the mitochondrial membrane induced by Fe2+-citrate. 1693 39

Since the discovery of HFE gene in 1996, considerable progress has been made concerning the iron-metabolism and its major abnormalities. Five types of hereditary hemochromatosis are actually known: type 1 (HFE gene), type 2A (HJV gene), type 2B (HAMP gene), type 3 (TfR2 gene), type 4 (SLC40A1 gene). The HFE C282Y +/+ mutation is responsible for the most frequent type of hemochromatosis in France. Various secondary causes can lead to iron-overload: associated genetic diseases, exogenous iron intake, thalassaemia and refractory anaemia, hepatic siderosis, alcoholic hepatitis, cutaneous porphyria and cirrhosis. The deleterious consequences of iron-overload are due to the interactions of the environmental factors. The role of HFE heterozygote mutations is still discussed. In clinical practice, the interpretation of a serum ferritin increase is a frequent problem that needs a careful evaluation based on the tranferrin saturation measurement. Significant increase of both these factors is in favour of an HFE C282Y +/+ hemochromatosis, after exclusion of a hepatocellular insufficiency or a refractory anaemia. Nevertheless, high ferritin is not always a marker of iron-overload. Thus, there are many disorders increasing the serum ferritin levels without iron overload : cytolysis (hepatic...), inflammatory or infectious syndromes, high alcohol intake, neoplasia... Looking for HFE mutations help to separate type 1 hemochromatosis from other conditions mainly hepatic siderosis (metabolic disorders). The identification of rare types of hemochromatosis (types 2-4) is only required in particular cases. The evaluation of the iron overload is now based on hepatic MRI determination rather than liver biopsy. Repeated phlebotomies remain the essential way to decrease the iron overload in HFE hemochromatosis and to prevent the occurrence of severe and irreversible complications (cirrhosis, arthropathies, cardiac failure, and diabetes). Because of the link established between the amount of iron-overload and the occurrence of complications and the mortality over-risk in HFE C282Y +/+ hemochromatosis, venesections must be started when serum ferritin is higher than 300 microg/l in man and 200 microg/l in woman, whatever the clinical manifestations are and obviously before the symptomatic phase of the disease.
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PMID:[Hereditary and acquired iron overload]. 1737 75

This communication explores the temporal link between the age-associated increase in body iron stores and the age-related incidence of Alzheimer's disease (AD), the most prevalent cause of senile dementia. Body iron stores that increase with age could be pivotal to AD pathogenesis and progression. Increased stored iron is associated with common medical conditions such as diabetes and vascular disease that increase risk for development of AD. Increased stored iron could also promote oxidative stress/free radical damage in vulnerable neurons, a critical early change in AD. A ferrocentric model of AD described here forms the basis of a rational, easily testable experimental therapeutic approach for AD, which if successful, would be both widely applicable and inexpensive. Clinical studies have shown that calibrated phlebotomy is an effective way to reduce stored iron safely and predictably without causing anemia. We hypothesize that reducing stored iron by calibrated phlebotomy to avoid iron deficiency will improve cerebrovascular function, slow neurodegenerative change, and improve cognitive and behavioral functions in AD. The hypothesis is eminently testable as iron reduction therapy is useful for chronic diseases associated with iron excess such as nonalcoholic steatohepatitis (NASH), atherosclerosis, hereditary hemochromatosis and thalassemia. Testing this hypothesis could provide valuable insight into the causation of AD and suggest novel preventive and treatment strategies.
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PMID:Getting the iron out: phlebotomy for Alzheimer's disease? 1919 95

Hereditary hemochromatosis is an iron overload disorder that can lead to the impairment of multiple organs and is caused by mutations in one or more different genes. Type 1 hemochromatosis is the most common form of the disease and results from mutations in the HFE gene. Juvenile hemochromatosis (JH) is the most severe form, usually caused by mutations in hemojuvelin (HJV) or hepcidin (HAMP). The autosomal dominant form of the disease, type 4, is due to mutations in the SLC40A1 gene, which encodes for ferroportin (FPN). Hereditary hemochromatosis is commonly found in populations of European origin. By contrast, hemochromatosis in Asia is rare and less well understood and can be masked by the presence of iron deficiency and secondary iron overload from thalassemia. Here, we provide a comprehensive report of hemochromatosis in a group of patients of Asian origin. We have identified novel mutations in HJV, HAMP, and SLC40A1 in countries not normally associated with hereditary hemochromatosis (Pakistan, Bangladesh, Sri Lanka, and Thailand). Our family studies show a high degree of consanguinity, highlighting the increased risk of iron overload in many countries of the developing world and in countries in which there are large immigrant populations from these regions.
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PMID:Iron overload in the Asian community. 1957 77

A few considerations, which we found in the literature, inspired us to reevaluate patients previously investigated [characterized for beta-thalassemia (beta-thal) and hereditary hemochromatosis (HH) genes] by our department at Medical Genetics, School of Medicine, University of Foggia, Italy.
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PMID:Coexistence of beta-thalassemia and hereditary hemochromatosis in homozygosity: a possible synergic effect? 1937 93

Historically, iron overload in the liver has been associated with the genetic disorders hereditary hemochromatosis and thalassemia and with unusual dietary habits. More recently, elevated hepatic iron levels also have been observed in chronic hepatitis C virus (HCV) infection. Iron overload in the liver causes many changes including induction of oxidative stress, damage to lysosomes and mitochondria, altered oxidant defense systems and stimulation of hepatocyte proliferation. Chronic HCV infection causes numerous pathogenic changes in the liver including induction of endoplasmic reticulum stress, the unfolded protein response, oxidative stress, mitochondrial dysfunction and altered growth control. Understanding the molecular and cellular changes that could occur in a liver which has elevated hepatic iron levels and in which HCV replication and gene expression are ongoing has clinical relevance and represents an area of research in need of further investigation.
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PMID:Elevated hepatic iron: a confounding factor in chronic hepatitis C. 1939 21

Deferasirox is a once-daily, orally administered, tridentate iron chelator that is indicated in the treatment of iron overload resulting from regular packed red blood cell transfusions in patients with transfusion-dependent anemias, such as beta-thalassemia, sickle cell disease, myelodysplastic syndrome and other rare anemias. Randomized, controlled trials have established its efficacy to reduce liver iron concentration and serum ferritin levels to be comparable to the historic standard iron chelator, deferoxamine, which is administered as a parenteral infusion. However, deferasirox may be more effective than deferoxamine in actual clinical practice owing to the improvement in quality of life and, hence, increased compliance associated with the oral route of administration. The higher acquisition cost of deferasirox may be counterbalanced by savings in the administration cost, as well as the treatment of complications of iron overload that result from noncompliance with therapy attributable to the parenteral mode of administration. Deferasirox may also have potential as an important supplement and even an alternative to phlebotomies in nontransfusional, genetic iron overload disorders, such as hereditary hemochromatosis.
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PMID:Pharmacoeconomic benefits of deferasirox in the management of iron overload syndromes. 1967 Sep 88

Deferasirox is a once-daily oral iron chelator with established dose-dependent efficacy in both adult and pediatric patients with transfusional iron overload. The clinical development program has demonstrated the efficacy of deferasirox for up to 4.5 years of treatment in patients with various underlying anemias, including beta-thalassemia, myelodysplastic syndromes, sickle cell disease, aplastic anemia, and other rare anemias. In addition to reducing key indicators of total body iron levels (serum ferritin, liver iron concentration, and toxic labile plasma iron), deferasirox has also demonstrated the ability to remove cardiac iron and prevent future cardiac iron accumulation. Emerging long-term data confirm the tolerability profile of deferasirox, and data on patient compliance render deferasirox a suitable therapeutic option for patients with chronic conditions requiring ongoing iron chelation therapy. Data continue to accumulate in a wide range of patient groups, including those with non-transfusion-dependent anemias such as hereditary hemochromatosis.
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PMID:Deferasirox (Exjade) for the treatment of iron overload. 1990 54

Millions of people are affected by hereditary hemochromatosis (HH) and thalassemia intermedia (TI), the iron overloading disorders caused by chronic increases in iron absorption. Genetic factors, regulatory pathways involving proteins of iron metabolism, non regulatory molecules, dietary constituents and iron binding drugs could affect iron absorption and could lead to iron overload or iron deficiency. Chelators and chelating drugs can affect both iron absorption and excretion. Deferoxamine (DFO), deferiprone (L1) and the DFO/L1 combination therapies have been used effectively for reversing the toxic side effects of iron overload including cardiac and liver damage in TI and HH patients where venesection is contraindicated. Selected protocols using DFO, L1 and their combination could be designed for optimizing chelation therapy in TI and HH. The use of deferasirox (DFRA) in HH and TI could cause an increase in iron and other toxic metal absorption. Future treatments of HH and TI could involve the use of iron chelating and other drugs not only for increasing iron excretion but also for preventing iron absorption.
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PMID:Iron chelation therapy in hereditary hemochromatosis and thalassemia intermedia: regulatory and non regulatory mechanisms of increased iron absorption. 2159 42


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