Iron overload (also known as haemochromatosis or hemochromatosis) is the abnormal and increased accumulation of total iron in the body, leading to organ damage.[1] The primary mechanism of organ damage is oxidative stress, as elevated intracellular iron levels increase free radical formation via the Fenton reaction. Iron overload is often primary (i.e. hereditary haemochromatosis) but may also be secondary to repeated blood transfusions (i.e. transfusional iron overload).[2] Iron deposition most commonly occurs in the liver, pancreas, skin, heart, and joints. People with iron overload classically present with the triad of liver cirrhosis, secondary diabetes mellitus, and bronze skin.[3] However, due to earlier detection nowadays, symptoms are often limited to general chronic malaise, arthralgia, and hepatomegaly.[3]
Iron overload | |
---|---|
Other names | Haemochromatosis or Hemochromatosis |
Micrograph of liver biopsy showing iron deposits due to haemosiderosis. Iron stain. | |
Specialty | Hematology, gastroenterology/hepatology |
Signs and symptoms
editOrgans most commonly affected by hemochromatosis include the liver, heart, and endocrine glands.[4]
Hemochromatosis may present with the following clinical syndromes:
- liver: chronic liver disease and cirrhosis of the liver.[5]
- heart: heart failure, cardiac arrhythmia.[5]
- hormones: diabetes (see below) and hypogonadism (insufficiency of the sex hormone producing glands) which leads to low sex drive and/or loss of fertility in men and loss of fertility and menstrual cycle in women.[5]
- metabolism: diabetes in people with iron overload occurs as a result of selective iron deposition in islet beta cells in the pancreas leading to functional failure and cell death.[6]
- skeletal: arthritis, from iron deposition in joints leading to joint pains. The most commonly affected joints are those of the hands, particularly the knuckles or metacarpophalangeal joints, wrists or radiocarpal joints, elbow, hip, knee and ankle joints.[7][8] Risk factors for the development of arthritis in those with hemochromatosis include elevated iron levels (ferritin greater than 1000 or transferrin saturation greater than 50%) for an extended period of time, increasing age and concurrent advanced liver fibrosis.[7]
- skin: melanoderma (darkening or 'bronzing' of the skin).[8][9]
Hemochromatosis leading to secondary diabetes (through iron deposition in the insulin secreting beta cells of the pancreas), when combined with a bronzing or darkening of the skin, is sometimes known as "bronze diabetes".[10]
Causes
editThe term hemochromatosis was initially used to refer to what is now more specifically called hemochromatosis type 1 (or HFE-related hereditary hemochromatosis). Currently, hemochromatosis (without further specification) is mostly defined as iron overload with a hereditary or primary cause,[11][12] or originating from a metabolic disorder.[13] However, the term is currently also used more broadly to refer to any form of iron overload, thus requiring specification of the cause, for example, hereditary hemochromatosis.
Primary hemochromatosis and hemosiderosis
editHereditary hemochromatosis
editHereditary hemochromatosis is an autosomal recessive disorder with estimated prevalence in the population of 1 in 200 among patients with European ancestry, with lower incidence in other ethnic groups.[14] Mutations of the HFE gene (hemostatic iron regulator) located on chromosome 6 (responsible for iron regulatory protein hepcidin production) are responsible for most cases of hereditary hemochromatosis; 95% of cases of hereditary hemochromatosis involve a mutation of this HFE gene.[1][7] Non-HFE hereditary hemochromatosis involves mutations in genes coding for the iron regulatory proteins hemojuvelin, transferrin receptor-2 and ferroportin.[7]
Hereditary hemochromatosis is characterized by an accelerated rate of intestinal iron absorption and progressive iron deposition in various tissues. This typically begins to be expressed in the third to fifth decades of life, but may occur in children. The most common presentation is hepatic cirrhosis in combination with hypopituitarism, cardiomyopathy, diabetes, arthritis, or hyperpigmentation. Because of the severe sequelae of this disorder if left untreated, and recognizing that treatment is relatively simple, early diagnosis before symptoms or signs appear is important.[15][16]
Hemosiderosis
editIn general, the term hemosiderosis is used to indicate the pathological effect of iron accumulation in any given organ, which mainly occurs in the form of the iron-storage complex hemosiderin.[17][18] Sometimes, the simpler term siderosis is used instead.
Other definitions distinguishing hemochromatosis or hemosiderosis that are occasionally used include:
- Hemosiderosis is hemochromatosis caused by excessive blood transfusions, that is, hemosiderosis is a form of secondary hemochromatosis.[19][20]
- Hemosiderosis is hemosiderin deposition within cells, while hemochromatosis is hemosiderin within cells and interstitium.[21]
- Hemosiderosis is iron overload that does not cause tissue damage,[22] while hemochromatosis does.[23]
- Hemosiderosis is arbitrarily differentiated from hemochromatosis by the reversible nature of the iron accumulation in the reticuloendothelial system.[24]
The causes of hemochromatosis broken down into two subcategories: primary cases (hereditary or genetically determined) and less frequent secondary cases (acquired during life).[25] People of Northern European descent, including Celtic (Irish, Scottish, Welsh, Cornish, Breton etc.), English, and Scandinavian origin[26] have a particularly high incidence, with about 10% being carriers of the principal genetic variant, the C282Y mutation on the HFE gene, and 1% having the condition.[27]
Non-classical hereditary hemochromatosis
editThe overwhelming majority depend on mutations of the HFE gene discovered in 1996, but since then others have been discovered and sometimes are grouped together as "non-classical hereditary hemochromatosis",[28] "non-HFE related hereditary hemochromatosis",[29] or "non-HFE hemochromatosis".[30]
Description | OMIM | Mutation |
---|---|---|
Hemochromatosis type 1: "classical" hemochromatosis | 235200 | HFE |
Hemochromatosis type 2A: juvenile hemochromatosis | 602390 | Haemojuvelin (HJV, also known as RGMc and HFE2) |
Hemochromatosis type 2B: juvenile hemochromatosis | 606464 | hepcidin antimicrobial peptide (HAMP) or HFE2B |
Hemochromatosis type 3 | 604250 | transferrin receptor-2 (TFR2 or HFE3) |
Hemochromatosis type 4 / African iron overload | 604653 | ferroportin (SLC11A3/SLC40A1) |
Neonatal hemochromatosis | 231100 | (unknown) |
Acaeruloplasminaemia (very rare) | 604290 | caeruloplasmin |
Congenital atransferrinaemia (very rare) | 209300 | transferrin |
GRACILE syndrome (very rare) | 603358 | BCS1L |
Most types of hereditary hemochromatosis have autosomal recessive inheritance, while type 4 has autosomal dominant inheritance.[31]
Secondary hemochromatosis
edit- Severe chronic hemolysis of any cause, including intravascular hemolysis and ineffective erythropoiesis (hemolysis within the bone marrow)
- Multiple frequent blood transfusions (either whole blood or just red blood cells), which are usually needed either by individuals with hereditary anaemias (such as beta-thalassaemia major, sickle cell anaemia, and Diamond–Blackfan anaemia) or by older patients with severe acquired anaemias such as in myelodysplastic syndromes.[6]
- Excess parenteral (non-ingested) iron supplements, such as what can acutely happen in iron poisoning
- Excess dietary iron
- Some disorders do not normally cause hemochromatosis on their own, but may do so in the presence of other predisposing factors. These include cirrhosis (especially related to alcohol use disorder), steatohepatitis of any cause, porphyria cutanea tarda, prolonged hemodialysis, and post-portacaval shunting
Pathophysiology
editDefects in iron metabolism, specifically involving the iron regulatory protein hepcidin are thought to play an integral role in the pathogenesis of hereditary hemochromatosis.[7]
Normally, hepcidin acts to reduce iron levels in the body by inhibiting intestinal iron absorption and inhibiting iron mobilization from stores in the bone marrow and liver.[7] Iron is absorbed from the intestines (mostly in the duodenum) and transported across intestinal enterocytes or mobilized out of storage in liver hepatocytes or from macrophages in the bone marrow by the transmembrane ferroportin transporter.[7] In response to elevated plasma iron levels, hepcidin inhibits the ferroportin transporter leading to decreased iron mobilization from stores and decreased intestinal iron absorption, thus functioning as a negative iron regulatory protein.[7]
In hereditary hemochromatosis, mutations in the proteins involved in hepcidin production including HFE (hemostatic iron regulator), hemojuvelin and transferrin receptor 2 lead to a loss or decrease in hepcidin production, which subsequently leads to the loss of the inhibitory signal regulating iron absorption and mobilization and thus leads to iron overload.[7] In very rare instances, mutations in ferroportin result in ferroportin resistance to hepcidin's negative regulatory effects, and continued intestinal iron absorption and mobilization despite inhibitory signaling from hepcidin.[7] Approximately 95% of cases of hereditary hemochromatosis are due to mutations in the HFE gene.[7]
The resulting iron overload causes iron to deposit in various sites throughout the body, especially the liver and joints, which coupled with oxidative stress leads to organ damage or joint damage and the pathological findings seen in hemochromatosis.[7]
Diagnosis
editThere are several methods available for diagnosing and monitoring iron overload.
Blood test
editBlood tests are usually the initial test if there is a clinical suspicion of iron overload. Serum ferritin testing is a low-cost, readily available, and minimally invasive method for assessing body iron stores. However ferritin levels may be elevated due to a variety of other causes including obesity, infection, inflammation (as an acute phase protein), chronic alcohol intake, liver disease, kidney disease, and cancer.[7][32][33] In males and postmenopausal females, normal range of serum ferritin is between 12 and 300 ng/mL (670 pmol/L) .[34][35][36] In premenopausal females, normal range of serum ferritin is between 12 and 150[34] or 200[35] ng/mL (330 or 440 pmol/L).[36] In those with hemochromatosis, the serum ferritin level correlates with the degree of iron overload.[7] Ferritin levels are usually monitored serially in those with hemochromatosis to assess response to treatment.[7]
Elevations in serum levels of the iron transporter protein transferrin saturation as well as increased red blood cell mean corpuscular volume and mean corpuscular hemoglobin concentration usually precede ferritin elevations in hemochromatosis.[7] Transferrin saturation of greater than 45% combined with an elevated ferritin level is highly sensitive in diagnosing HFE hemochromatosis.[7] Total iron binding capacity may be low in hemochromatosis, but can also be normal.[37]
Genetics
editGeneral screening for hemochromatosis is not recommended, however first-degree relatives of those affected should be screened.[7][38][39][40]
Once iron overload has been established, HFE gene mutation genetic testing for hereditary causes of iron overload is indicated.[39][15] The presence of HFE gene mutations in addition to iron overload confirms the clinical diagnosis of hereditary hemochromatosis.[39] The alleles evaluated by HFE gene analysis are evident in ~80% of patients with hemochromatosis; a negative report for HFE gene does not rule out hemochromatosis.[citation needed]
Biopsy
editLiver biopsy is the removal of small sample in order to be studied and can determine the cause of inflammation or cirrhosis. In someone with negative HFE gene testing, elevated iron status for no other obvious reason, and family history of liver disease, additional evaluation of liver iron concentration is indicated. In this case, diagnosis of hemochromatosis is based on biochemical analysis and histologic examination of a liver biopsy. Assessment of the hepatic iron index (HII) is considered the "gold standard" for diagnosis of hemochromatosis.[citation needed]
Imaging
editMagnetic resonance imaging (MRI) is used as a noninvasive method to estimate iron deposition levels in the liver and heart, which may aid in determining a response to treatment or prognosis.[7] Liver elastography has limited utility in detecting liver fibrosis in hemochromatosis.[7]
Treatment
editPhlebotomy
editPhlebotomy, bloodletting or venesection is the mainstay of treatment in iron overload, consisting of regularly scheduled blood draws to remove red blood cells (and iron) from the body.[7] Upon initial diagnosis of iron overload, the phlebotomies may be performed weekly or twice weekly, until iron levels are normalized. Once the serum ferritin and transferrin saturation are within the normal range, maintenance phlebotomies may be needed in some (depending upon the rate of reabsorption of iron), scheduled at varying frequencies to keep iron stores within normal range.[39] A phlebotomy session typically draws between 450 and 500 mL of blood.[42] Routine phlebotomy may reverse liver fibrosis and alleviate some symptoms of hemochromatosis, but chronic arthritis is usually not responsive to treatment.[7] In those with hemochromatosis; the blood drawn during phlebotomy is safe to be donated.[43][39]
Phlebotomy is associated with improved survival if it is initiated before the onset of cirrhosis or diabetes.[39]
Diet
editThe human diet contains iron in two forms: heme iron and non-heme iron. Heme iron is usually found in red meat, whereas non-heme iron is found in plant based sources. Heme iron is the most easily absorbed form of iron. In those with hemochromatosis undergoing phlebotomy for treatment; restriction of dietary iron is not required.[39][40][7] However, those who do restrict dietary iron usually require less phlebotomy (about 0.5–1.5 liters of blood less per year).[44] Vitamin C and iron supplementation should be avoided as vitamin C accelerates intestinal absorption of iron and mobilization of body iron stores.[39][40] Raw seafood should be avoided because of increased risk of infections from iron loving pathogens such as Vibrio vulnificus.[7][45] Alcohol consumption should be avoided due to the risk of compounded liver damage with iron overload.[7]
Medication
editMedications are used for those unable to tolerate routine blood draws, there are chelating agents available for use.[46] The drug deferoxamine binds with iron in the bloodstream and enhances its elimination in urine and faeces. Typical treatment for chronic iron overload requires subcutaneous injection over a period of 8–12 hours daily.[citation needed] Two newer iron-chelating drugs that are licensed for use in patients receiving regular blood transfusions to treat thalassaemia (and, thus, who develop iron overload as a result) are deferasirox and deferiprone.[47][48]
Chelating polymers
editA minimally invasive approach to hereditary hemochromatosis treatment is the maintenance therapy with polymeric chelators.[49][50][51] These polymers or particles have a negligible or null systemic biological availability and they are designed to form stable complexes with Fe2 and Fe3 in the GIT and thus limiting their uptake and long-term accumulation. Although this method has only a limited efficacy, unlike small-molecular chelators, the approach has virtually no side effects in sub-chronic studies.[51] Interestingly, the simultaneous chelation of Fe2 and Fe3 increases the treatment efficacy.[51]
Prognosis
editIn general, provided there has been no liver damage, patients should expect a normal life expectancy if adequately treated by venesection. If the serum ferritin is greater than 1,000 μg/L at diagnosis there is a risk of liver damage and cirrhosis which may eventually shorten their life.[52] The presence of cirrhosis increases the risk of hepatocellular carcinoma.[53] Other risk factors for liver damage in hemochromatosis include alcohol use, diabetes, liver iron levels greater than 2,000 μmol/gram and increased aspartate transaminase levels.[7]
The risk of death and liver fibrosis are elevated in males with HFE type hemochromatosis but not in females; this is thought to be due to a protective effect of menstruation and pregnancy seen in females as well as possible hormone-related differences in iron absorption.[7]
Epidemiology
editHHC is most common in certain European populations (such as those of Irish or Scandinavian descent) and occurs in 0.6% of some unspecified population.[38] Men have a 24-fold increased rate of iron-overload disease compared with women.[38]
Stone Age
editDiet and the environment are thought to have had large influence on the mutation of genes related to iron overload. Starting during the Mesolithic era, communities of people lived in an environment that was fairly sunny, warm and had the dry climates of the Middle East. Most humans who lived at that time were foragers and their diets consisted largely of wild plants, fish, and game. Archaeologists studying dental plaque have found evidence of tubers, nuts, plantains, grasses and other foods rich in iron. Over many generations, the human body became well-adapted to a high level of iron content in the diet.[54]
Neolithic
editIn the Neolithic era, significant changes are thought to have occurred in both the environment and diet. Some communities of foragers migrated north, leading to changes in lifestyle and environment, with a decrease in temperatures and a change in the landscape which the foragers then needed to adapt to. As people began to develop and advance their tools, they learned new ways of producing food, and farming also slowly developed. These changes would have led to serious stress on the body and a decrease in the consumption of iron-rich foods. This transition is a key factor in the mutation of genes, especially those that regulated dietary iron absorption. Iron, which makes up 70% of red blood cell composition, is a critical micronutrient for effective thermoregulation in the body.[55] Iron deficiency will lead to a drop in the core temperature. In the chilly and damp environments of Northern Europe, supplementary iron from food was necessary to keep temperatures regulated, however, without sufficient iron intake the human body would have started to store iron at higher rates than normal. In theory, the pressures caused by migrating north would have selected for a gene mutation that promoted greater absorption and storage of iron.[56]
Viking hypothesis
editStudies and surveys conducted to determine the frequencies of hemochromatosis help explain how the mutation migrated around the globe. In theory, the disease initially evolved from travelers migrating from the north. Surveys show a particular distribution pattern with large clusters and frequencies of gene mutations along the western European coastline.[57] This led the development of the "Viking Hypothesis".[58] Cluster locations and mapped patterns of this mutation correlate closely to the locations of Viking settlements in Europe established c.700 AD to c.1100 AD. The Vikings originally came from Norway, Sweden and Denmark. Viking ships made their way along the coastline of Europe in search of trade, riches, and land. Genetic studies suggest that the extremely high frequency patterns in some European countries are the result of migrations of Vikings and later Normans, indicating a genetic link between hereditary hemochromatosis and Viking ancestry.[59]
Modern times
editIn 1865, Armand Trousseau (a French internist) was one of the first to describe many of the symptoms of a diabetic patient with cirrhosis of the liver and bronzed skin color. The term hemochromatosis was first used by German pathologist Friedrich Daniel von Recklinghausen in 1889 when he described an accumulation of iron in body tissues.[60]
Identification of genetic factors
editAlthough it was known most of the 20th century that most cases of hemochromatosis were inherited, they were incorrectly assumed to depend on a single gene.[61]
In 1935 J.H. Sheldon, a British physician, described the link to iron metabolism for the first time as well as demonstrating its hereditary nature.[60]
In 1996 Felder and colleagues identified the hemochromatosis gene, HFE gene. Felder found that the HFE gene has two main mutations, causing amino acid substitutions C282Y and H63D, which were the main cause of hereditary hemochromatosis.[60][62] The next year the CDC and the National Human Genome Research Institute sponsored an examination of hemochromatosis following the discovery of the HFE gene, which helped lead to the population screenings and estimates that are still being used today.[63]
See also
editReferences
edit- ^ a b Hsu CC, Senussi NH, Fertrin KY, Kowdley KV (June 2022). "Iron overload disorders". Hepatol Commun. 6 (8): 1842–54. doi:10.1002/hep4.2012. PMC 9315134. PMID 35699322.
- ^ Hider RC, Kong X (2013). "Iron: Effect of Overload and Deficiency". In Astrid Sigel, Helmut Sigel and Roland K. O. Sigel (ed.). Interrelations between Essential Metal Ions and Human Diseases. Metal Ions in Life Sciences. Vol. 13. Springer. pp. 229–94. doi:10.1007/978-94-007-7500-8_8. ISBN 978-94-007-7499-5. PMID 24470094.
- ^ a b Daniłowicz-Szymanowicz L, Świątczak M, Sikorska K, Starzyński RR, Raczak A, Lipiński P (2021-07-16). "Pathogenesis, Diagnosis, and Clinical Implications of Hereditary Hemochromatosis-The Cardiological Point of View". Diagnostics (Basel, Switzerland). 11 (7): 1279. doi:10.3390/diagnostics11071279. ISSN 2075-4418. PMC 8304945. PMID 34359361.
- ^ Andrews NC (1999). "Disorders of Iron Metabolism". New England Journal of Medicine. 341 (26): 1986–95. doi:10.1056/NEJM199912233412607. PMID 10607817.
- ^ a b c John Murtagh (2007). General Practice. McGraw Hill Australia. ISBN 978-0-07-470436-3.[page needed]
- ^ a b Lu JP (1994). "Selective iron deposition in pancreatic islet B cells of transfusional iron-overloaded autopsy cases". Pathol Int. 44 (3): 194–99. doi:10.1111/j.1440-1827.1994.tb02592.x. PMID 802561. S2CID 25357672.
- ^ a b c d e f g h i j k l m n o p q r s t u v w x y z aa Olynyk JK, Ramm GA (8 December 2022). "Hemochromatosis". New England Journal of Medicine. 387 (23): 2159–70. doi:10.1056/NEJMra2119758. PMID 36477033. S2CID 254432917.
- ^ a b Bruce R Bacon, Stanley L Schrier. "Patient information: Hemochromatosis (hereditary iron overload) (Beyond the Basics)". UpToDate. Retrieved 2016-07-14. Literature review current through: Jun 2016. | This topic last updated: Apr 14, 2015.
- ^ Brissot P, Pietrangelo A, Adams PC, de Graaff B, McLaren CE, Loréal O (5 April 2018). "Haemochromatosis". Nature Reviews. Disease Primers. 4: 18016. doi:10.1038/nrdp.2018.16. PMC 7775623. PMID 29620054.
- ^ "Haemochromatosis and diabetes". Diabetes UK.
- ^ thefreedictionary.com > hemochromatosis, citing:
- The American Heritage Medical Dictionary, 2004 by Houghton Mifflin Company
- McGraw-Hill Concise Dictionary of Modern Medicine. 2002
- ^ Merriam-Webster's Medical Dictionary > hemochromatosis Retrieved on December 11, 2009
- ^ thefreedictionary.com, citing:
- Dorland's Medical Dictionary for Health Consumers, 2007
- Mosby's Medical Dictionary, 8th edition. 2009
- Jonas: Mosby's Dictionary of Complementary and Alternative Medicine. 2005.
- ^ "Hemochromatosis". Archived from the original on 2007-03-18. Retrieved 2012-10-05.
- ^ a b Pietrangelo A (2010). "Hereditary Hemochromatosis: Pathogenesis, Diagnosis, and Treatment". Gastroenterology. 139 (2): 393–408. doi:10.1053/j.gastro.2010.06.013. PMID 20542038.
- ^ Brandhagen DJ, Fairbanks VF, Batts KP, Thibodeau SN (1999). "Update on hereditary hemochromatosis and the HFE gene". Mayo Clinic Proceedings. 74 (9): 917–21. doi:10.4065/74.9.917. PMID 10488796.
- ^ Merriam-Webster's Medical Dictionary > hemosideroses Retrieved on December 11, 2009
- ^ thefreedictionary.com > hemosiderosis, citing:
- The American Heritage Medical Dictionary, 2004 by Houghton Mifflin Company
- Mosby's Medical Dictionary, 8th edition.
- ^ eMedicine Specialties > Radiology > Gastrointestinal > Hemochromatosis Author: Sandor Joffe, MD. Updated: May 8, 2009
- ^ thefreedictionary.com > hemosiderosis, citing:
- Gale Encyclopedia of Medicine. Copyright 2008
- ^ Notecards on radiology gamuts, diseases, anatomy Archived 2010-07-21 at the Wayback Machine 2002, Charles E. Kahn, Jr., MD. Medical College of Wisconsin
- ^ thefreedictionary.com > hemosiderosis, citing:
- Dorland's Medical Dictionary for Health Consumers, 2007
- Mosby's Dental Dictionary, 2nd ed.
- Saunders Comprehensive Veterinary Dictionary, 3rd ed. 2007
- ^ The HealthScout Network > Health Encyclopedia > Diseases and Conditions > Hemochromatosis Archived 2010-02-09 at the Wayback Machine Retrieved on December 11, 2009
- ^ thefreedictionary.com > hemosiderosis, citing:
- McGraw-Hill Concise Dictionary of Modern Medicine. 2002
- ^ Pietrangelo A (2003). "Haemochromatosis". Gut. 52 (95002): ii23–30. doi:10.1136/gut.52.suppl_2.ii23. PMC 1867747. PMID 12651879.
- ^ The Atlantic: "The Iron in Our Blood That Keeps and Kills Us" by Bradley Wertheim January 10, 2013
- ^ "Hemachromatosis". Encyclopædia Britannica.com. Retrieved 17 April 2017.
- ^ Mendes AI, Ferro A, Martins R, Picanço I, Gomes S, Cerqueira R, Correia M, Nunes AR, Esteves J, Fleming R, Faustino P (2008). "Non-classical hereditary hemochromatosis in Portugal: novel mutations identified in iron metabolism-related genes" (PDF). Annals of Hematology. 88 (3): 229–34. doi:10.1007/s00277-008-0572-y. PMID 18762941. S2CID 23206256.
- ^ Maddrey, Willis C., Schiff, Eugene R., Sorrell, Michael F. (2007). Schiff's diseases of the liver. Hagerstwon, MD: Lippincott Williams & Wilkins. p. 1048. ISBN 978-0-7817-6040-9.
- ^ Pietrangelo A (2005). "Non-HFE Hemochromatosis". Seminars in Liver Disease. 25 (4): 450–60. doi:10.1055/s-2005-923316. PMID 16315138. S2CID 260320984.
- ^ Franchini M (2006). "Hereditary iron overload: Update on pathophysiology, diagnosis, and treatment". American Journal of Hematology. 81 (3): 202–09. doi:10.1002/ajh.20493. PMID 16493621.
- ^ Waalen J, Felitti VJ, Gelbart T, Beutler E (1 April 2008). "Screening for hemochromatosis by measuring ferritin levels: a more effective approach". Blood. 111 (7): 3373–76. doi:10.1182/blood-2007-07-102673. PMC 2275006. PMID 18025154.
- ^ Koperdanova M, Cullis JO (3 August 2015). "Interpreting raised serum ferritin levels". BMJ. 351: h3692. doi:10.1136/bmj.h3692. PMID 26239322. S2CID 44923011.
- ^ a b Ferritin by: Mark Levin, MD, Hematologist and Oncologist, Newark, NJ. Review provided by VeriMed Healthcare Network
- ^ a b Andrea Duchini. "Hemochromatosis Workup". Medscape. Retrieved 2016-07-14. Updated: Jan 02, 2016
- ^ a b Molar concentration is derived from mass value using molar mass of 450,000 g•mol−1 for ferritin
- ^ labtestsonline.org TIBC & UIBC, Transferrin Last reviewed on October 28, 2009.
- ^ a b c Crownover BK, Covey, CJ (Feb 1, 2013). "Hereditary hemochromatosis". American Family Physician. 87 (3): 183–90. PMID 23418762.
- ^ a b c d e f g h Bacon BR, Adams PC, Kowdley KV, Powell LW, Tavill AS (July 2011). "Diagnosis and management of hemochromatosis: 2011 Practice Guideline by the American Association for the Study of Liver Diseases". Hepatology. 54 (1): 328–43. doi:10.1002/hep.24330. PMC 3149125. PMID 21452290. S2CID 9311604.
- ^ a b c Kowdley KV, Brown KE, Ahn J, Sundaram V (August 2019). "ACG Clinical Guideline: Hereditary Hemochromatosis". American Journal of Gastroenterology. 114 (8): 1202–18. doi:10.14309/ajg.0000000000000315. PMID 31335359. S2CID 198192589.
- ^ Image by Mikael Häggström, MD. Source for mesenchymal versus parenchymal iron overload Deugnier Y, Turlin B (2007). "Pathology of hepatic iron overload". World J Gastroenterol. 13 (35): 4755–60. doi:10.3748/wjg.v13.i35.4755. PMC 4611197. PMID 17729397.
- ^ Barton JC (1 December 1998). "Management of Hemochromatosis". Annals of Internal Medicine. 129 (11_Part_2): 932–39. doi:10.7326/0003-4819-129-11_Part_2-199812011-00003. PMID 9867745. S2CID 53087679.
- ^ NIH blood bank. "Hemochromatosis Donor Program".
- ^ Moretti D, Van Doorn GM, Swinkels DW, Melse-Boonstra A (2013). "Relevance of dietary iron intake and bioavailability in the management of HFE hemochromatosis: A systematic review". The American Journal of Clinical Nutrition. 98 (2): 468–79. doi:10.3945/ajcn.112.048264. PMID 23803887.
- ^ Bullen JJ (1 August 1991). "Hemochromatosis, Iron, and Septicemia Caused by Vibrio vulnificus". Archives of Internal Medicine. 151 (8): 1606–09. doi:10.1001/archinte.1991.00400080096018. PMID 1872665.
- ^ Miller MJ (1989-11-01). "Syntheses and therapeutic potential of hydroxamic acid based siderophores and analogs". Chemical Reviews. 89 (7): 1563–79. doi:10.1021/cr00097a011.
- ^ Choudhry VP, Naithani R (2007). "Current status of iron overload and chelation with deferasirox". Indian J Pediatr. 74 (8): 759–64. doi:10.1007/s12098-007-0134-7. PMID 17785900. S2CID 19930076.
- ^ Hoffbrand AV (20 March 2003). "Role of deferiprone in chelation therapy for transfusional iron overload". Blood. 102 (1): 17–24. doi:10.1182/blood-2002-06-1867. PMID 12637334.
- ^ Polomoscanik SC, Cannon CP, Neenan TX, Holmes-Farley SR, Mandeville WH, Dhal PK (2005). "Hydroxamic Acid-Containing Hydrogels for Nonabsorbed Iron Chelation Therapy: Synthesis, Characterization, and Biological Evaluation". Biomacromolecules. 6 (6): 2946–53. doi:10.1021/bm050036p. ISSN 1525-7797. PMID 16283713.
- ^ Qian J, Sullivan BP, Peterson SJ, Berkland C (2017). "Nonabsorbable Iron Binding Polymers Prevent Dietary Iron Absorption for the Treatment of Iron Overload". ACS Macro Letters. 6 (4): 350–53. doi:10.1021/acsmacrolett.6b00945. ISSN 2161-1653. PMID 35610854.
- ^ a b c Groborz O, Poláková L, Kolouchová K, Švec P, Loukotová L, Miriyala VM, Francová P, Kučka J, Krijt J, Páral P, Báječný M, Heizer T, Pohl R, Dunlop D, Czernek J, Šefc L, Beneš J, Štěpánek P, Hobza P, Hrubý M (2020). "Chelating Polymers for Hereditary Hemochromatosis Treatment". Macromolecular Bioscience. 20 (12): 2000254. doi:10.1002/mabi.202000254. ISSN 1616-5187. PMID 32954629. S2CID 221827050.
- ^ Allen KJ, Gurrin LC, Constantine CC, Osborne NJ, Delatycki MB, Nicoll AJ, McLaren CE, Bahlo M, Nisselle AE, Vulpe CD, Anderson GJ, Southey MC, Giles GG, English DR, Hopper JL, Olynyk JK, Powell LW, Gertig DM (17 January 2008). "Iron-overload-related disease in HFE hereditary hemochromatosis" (PDF). The New England Journal of Medicine. 358 (3): 221–30. doi:10.1056/NEJMoa073286. PMID 18199861.
- ^ Kowdley KV (November 2004). "Iron, hemochromatosis, and hepatocellular carcinoma". Gastroenterology. 127 (5 Suppl 1): S79–86. doi:10.1016/j.gastro.2004.09.019. PMID 15508107.
- ^ "The Evolution of Diet". National Geographic. Retrieved 2018-04-11.
- ^ Rosenzweig PH, Volpe SL (March 1999). "Iron, thermoregulation, and metabolic rate". Critical Reviews in Food Science and Nutrition. 39 (2): 131–148. doi:10.1080/10408399908500491. ISSN 1040-8398. PMID 10198751.
- ^ Heath KM, Axton JH, McCullough JM, Harris N (May 2016). "The evolutionary adaptation of the C282Y mutation to culture and climate during the European Neolithic". American Journal of Physical Anthropology. 160 (1): 86–101. doi:10.1002/ajpa.22937. ISSN 0002-9483. PMC 5066702. PMID 26799452.
- ^ "Clinical Penetrance of HFE Hereditary Hemochromatosis, Serum Ferritin Levels, and Screening Implications: Can We Iron This Out?". www.hematology.org. 2008-05-01. Archived from the original on 2018-06-15. Retrieved 2018-04-11.
- ^ Symonette CJ, Adams PC (June 2011). "Do all hemochromatosis patients have the same origin? A pilot study of mitochondrial DNA and Y-DNA". Canadian Journal of Gastroenterology. 25 (6): 324–326. doi:10.1155/2011/463810. ISSN 0835-7900. PMC 3142605. PMID 21766093.
- ^ "Videos: Hereditary Hemochromatosis | Canadian Hemochromatosis Society". www.toomuchiron.ca. Archived from the original on 2018-04-11. Retrieved 2018-04-11.
- ^ a b c Fitzsimons EJ, Cullis JO, Thomas DW, Tsochatzis E, Griffiths WJ, the British Society for Haematology (May 2018). "Diagnosis and therapy of genetic haemochromatosis (review and 2017 update)". British Journal of Haematology. 181 (3): 293–303. doi:10.1111/bjh.15164. PMID 29663319.
- ^ Cam Patterson, Marschall S. Runge (2006). Principles of molecular medicine. Totowa, NJ: Humana Press. p. 567. ISBN 978-1-58829-202-5.
- ^ Feder J, Gnirke A, Thomas W, Tsuchihashi Z, Ruddy D, Basava A, Dormishian F, Domingo R, Ellis M (August 1996). "A novel MHC class I–like gene is mutated in patients with hereditary haemochromatosis". Nature Genetics. 13 (4): 399–408. doi:10.1038/ng0896-399. PMID 8696333. S2CID 26239768.
- ^ Burke W, Thomson E, Khoury MJ, McDonnell SM, Press N, Adams PC, Barton JC, Beutler E, Brittenham G (1998-07-08). "Hereditary Hemochromatosis: Gene Discovery and Its Implications for Population-Based Screening". JAMA. 280 (2): 172–78. doi:10.1001/jama.280.2.172. ISSN 0098-7484. PMID 9669792.