Hemochromatosis Information and Courses from MediaLab, Inc.

Hereditary hemochromatosis (HH) is a disorder of iron regulation that results in excessive dietary iron absorption through the gastrointestinal tract. Over time, the resultant iron overload and its deposition in tissue may lead to widespread organ damage, a variety of chronic disorders, and even death. Although it is a genetic disorder, clinical symptoms most typically become apparent in middle aged adults. Iron overload occurs in a variety of hereditary and acquired forms, known as iron storage diseases. HH is the most common cause of inherited iron overload. (1) Due to lack of awareness, HH often goes undetected or unrecognized by health care providers. Early detection to prevent the serious complications associated with iron overload has important consequences for reducing morbidity and mortality. Laboratory tests that assess iron levels and molecular assays for genetic mutatations are essential for both its detection and diagnosis.

Tests for evaluating iron metabolism are generally used as initial or screening tests for hereditary hemochromatosis (HH) as they will detect the phenotypic expression of HH. These tests include serum iron (SI), transferrin (Tf) or total iron binding capacity (TIBC), serum ferritin (SF), and unsaturated iron binding capacity (UIBC).The serum ferritin assay is also used to assess the effectiveness of HH treatment.Molecular (DNA) analyses for HFE mutations are considered to be confirmatory tests for HH which may be ordered reflexively in patients with elevated iron results. Laboratories should establish their own reference intervals for assays of iron metabolism. In general, reference intervals vary by sex and by method used for the assays discussed in the following section. Typical reference intervals are included in the following sections for instructive purposes only and should not be used for evaluating actual patient data.The results of laboratory tests assessing iron metabolism should be interpreted with caution because a number of pre-analytical and physiologic factors can affect the results. Repeating elevated test results on fasting specimens is often advisable.

1. Beutler E. Iron storage disease: Facts, fiction and progress. Blood Cells Mol Dis. 2007;39:140-7.2. Higgins T, Beutler E, Doumas BT. Hemoglobin, iron, and bilirubin. In: Burtis CA, editor. Teitz Fundamentals of Clinical Chemistry. 6th ed. Saunders Elsevier, 2008.3. Ganz T. Hepcidin, a key regulator of iron metabolism and mediator of anemia and inflammation. Blood 2003;102(3):78-8.4. Andrews NC, Schmidt PJ. Iron homeostasis. Annu Rev Physiolo. 2007;69:69-85.5. Murtagh LJ, Whiley M, Wilson S, et al. Unsaturated iron binding capacity and transferrin saturation are equally reliable in detection of HFE hemochromatosis. Am J Gastroenterol. 2002;97(8):2093-9.6. Haddy TB, Castro OL, Rana SR. Hereditary hemochromatosis in children, adolescents, and young adults. Am J Pediatr Hematol Oncol 1988;10:23-4.7. Edwards CQ, Ajoika RS, Kushner JP. Hemochromatosis: A genetic definition. In Barton JC, Edwards CQ, eds. Hemochromatosis: Genetics, Pathophysiology, Diagnosis and Treatment. Cambridge, UK:Cambridge Univ Pr 2000:8-11.8. Whitlock EP, Garlitz BA, Harris EL , et al. Screening for Hereditary Hemochromatosis: A Systematic Review for the U.S. Preventive Services Task Force. Ann Intern Med. 2006; 145: 209-23.9. Wallace DF, Subramaniam VN. Non-HFE haemaochromatosis. World J Gastroenterol. 2007;13(35):4690-8.10. Tavill AS. Diagnosis and management of hemochromatosis. Hepatology. 2001;33:1321-811. Qaseem A, Aronson M, Fitterman N, Snow V, Weiss KB, Owens DK, et al. Screening for hereditary hemochromatosis: a clinical practice guideline from the American College of Physicians. Ann Intern Med. 2005;143:517-21.12. Phatak PD, Bonkovsky HL, and Kowdley KV. Hereditary Hemochromatosis: time for targeted screening. Ann Intern Med. 2008; 149(4): 270 – 2.13. Brissot P, deBels F. Current approaches to the management of hemochromatosis. Hematology Am Soc Hematol Educ Program. 2006:36-41. 14. Guidance for industry: Variances for blood collection from individuals with hereditary hemochromatosis. http://www.fda.gov/cber/gdlns/hemchrom.htm Accessed 12/17/08.

Hereditary hemochromatosis (HH) is a genetic disorder characterized by iron overload as a result of increased iron absorption. As iron absorption increases, the amount of iron bound to transferrin and transported in the plasma subsequently increases.With no available mechanism for excreting excess absorbed iron, normal iron storage sites become overloaded, resulting in ferritin levels that far exceed normal. As a result, iron is deposited in the parenchymal cells of the liver, pancreas, pituitary, heart, synovium, and other tissues with high concentrations of transferrin receptors. Iron in excess of normal cellular ferritin stores contributes to the generation of free radicals and reactive oxygen intermediates that cause cell damage to organs and tissues. This process results in the clinical condition known as iron overload, a hallmark feature of HH.

Genes in addition to HFE have been linked to hereditary hemochromatosis (HH). They include the hepcidin, hemojuvelin, transferrin receptor, and ferroportin genes. Mutations of some are linked with dominantly inherited HH, juvenile HH, and African iron overload. Unlike HH due to HFE mutations, these clinical disorders are rarely observed in the US population.(9)

Hereditary hemochromatosis (HH) is frequently discovered only during management of associated illness or routine health evaluations. It has been estimated that only a small percentage of all affected persons are actually diagnosed. Individuals with HH may be symptomatic for several years prior to diagnosis and may have consulted multiple health care providers.Under-diagnosis of HH is thought to occur due to:• Lack of specificity of early signs and symptoms• Asymptomatic status of some patients until damage to organs and tissues has occurred• Confusion with liver disease due to other causes• Insufficient awareness and knowledge of HHEarly identification of persons with HH is essential to prevent serious and irreversible complications associated with severe iron overload. A classic triad of skin hyperpigmentation (bronzing), type 2 diabetes, and hepatic cirrhosis has long been recognized as evidence of advanced iron overload. However, persons with HH may present with a much wider variety of signs and symptoms, particularly if they are seen before significant iron accumulation has occurred. Age of presentation and disease severity are highly variable. A diagnosis of HH is based on laboratory evidence of iron overload, genetic mutations associated with HH, and presence of clinical signs and symptoms consistent with HH.(10)

Early signs and symptoms of hereditary hemochromatosis (HH) are vague, nonspecific, and variable. As iron overload progresses (late HH), signs and symptoms become more severe and are related to damage of specific organs.

In addition to hereditary hemochromatosis (HH), there are other conditions of iron overload that must be considered in a differential diagnosis. Disorders such as sickle cell disease, thalassemia, sideroblastic anemia, congenital dyserythropoietic anemia, and liver disease may also cause iron overload. Transfusion-dependant patients and persons who abuse iron-containing vitamin supplements are also at risk. These conditions are usually described as secondary iron overload, in contrast to the primary iron overload of HH.Patient history, clinical signs and symptoms, biochemical and hematologic laboratory analyses, and possibly results of a liver biopsy may be needed to establish a diagnosis of a condition causing secondary iron overload. DNA tests for common HFE mutations are very likely the most important diagnostic tool for identifying HH as the cause of iron overload. In some patients, both secondary causes and HH may be contributing to iron overload. Differentiating the secondary causes of iron overload from HH is heavily dependent on the results of laboratory assays, but a complete discussion is beyond the scope of this course.

The diagnosis of hereditary hemochromatosis (HH) is made through a combination of laboratory tests and medical evaluation of a patient's signs and symptoms. Iron overload is identified by tests that evaluate iron metabolism, while molecular assays are needed to document mutations in the HFE gene or others such as hepcidin, hemojuvelin, or transferrin receptor. Individuals with documented iron overload who exhibit signs and symptoms consistent with HH and who possess HFE or other mutations are considered to have HH. Other causes of secondary iron overload may need to be ruled out.An example of a testing algorithm is shown.

The major determinant of prognosis in cases of hereditary hemochromatosis (HH) is the degree of organ damage from iron overload at the point of diagnosis. The presence of liver cirrhosis reduces life expectancy. Damage that has occurred to tissues and organs is irreversible, but further damage can be halted with treatment. When there is no evidence of cirrhosis at time of diagnosis, life expectancy may be equal to that of persons without HH. With proper management of HH through treatment, affected individuals have good long-term outcomes. Hepatocellular carcinoma associated with cirrhosis, hepatic failure, and cardiac failure are the most common causes of death in persons with HH. Compared to the normal population, liver cancer is many times more prevalent as a cause of death in persons with HH. Cardiomyopathy, diabetes, and cirrhosis are all more common causes of death among persons with HH than among normal persons. The earlier HH is detected, before the onset of severe organ damage, the lower the risk of mortality.

Serum iron (SI) is a measure of circulating iron bound to transferrin and is reflective of total body iron. SI is elevated in hereditary hemochromatosis (HH) and acute hepatitis. SI is decreased in iron deficiency anemia and chronic inflammation. SI concentrations exhibit diurnal variation, with the lowest values occurring around midnight. In addition, specimens collected from the same individual at the same time of the day may exhibit day to day variations as high as 40%. SI determinations are also affected by diet, menstrual cycle, pregnancy, ingestion of iron supplements, and oral contraceptive use. SI levels alone are considered insensitive indicators of HH. SI is typically measured on automated analyzers using spectrophotometric methods. Iron in the sample is released from transferrin with an acid reagent, reduced to the ferrous state, and reacted with a chromogen such as bathophenanthroline or ferrozine. The intensity of the color change is proportional to the iron concentration. Interference can arise from the use of a hemolyzed sample and contamination of reagents and water with iron. A typical reference interval for SI is 60 - 150 micrograms/dL. SI is usually ordered along with its companion test, the total iron binding capacity (TIBC), or with transferrin (Tf).(2)

DNA tests for HFE mutations associated with hereditary hemochromatosis (HH) are available in some clinical laboratories and reference laboratories. Testing for the presence of the C282Y is essential, although most labs also test for H63D and S65C mutations. Molecular testing is most appropriate for confirmatory testing of symptomatic individuals with altered iron studies (increased TS and SF), in pre-symptomatic individuals (increased TS, normal SF and liver function tests), and in family members of individuals diagnosed with HH. The use of genetic tests alone for routine screening of asymptomatic persons is not recommended for several reasons. A positive test indicating the presence of HFE mutations does not guarantee that an individual will develop clinically significant iron overload or predict severity of symptoms. A negative result (no HFE mutations present) does not rule out a diagnosis of iron overload because of genetic heterogeneity. Compared to biochemical analyses for iron, molecular assays are expensive. Finally, molecular testing may result in the diagnosis of a genetic disease, thus opening up the possibility for discrimination in health insurance coverage. Using molecular methods, DNA is extracted from leukocytes in whole blood samples or from buccal cells and analyzed for specific HFE mutations using polymerase chain reaction (PCR) with melt curve analysis. Currently there are no FDA-cleared products for HFE testing, and testing laboratories are using "home brew" reagents. This situation is expected to change as manufacturers submit products for FDA approval.

Measuring the amount of iron deposited in the liver is considered definitive for iron overload. This may be done by liver biopsy, computed tomography (CT), or magnetic resonance imaging (MRI). Demonstrating iron in parenchymal liver cells helps determine disease severity. Liver sections obtained by biopsy are stained with Perls Prussian blue which stains iron present in parenchymal cells. A photomicrograph of this reaction is shown.Although liver biopsy may not be necessary for diagnosing hereditary hemochromatosis (HH), it offers the advantage of detecting liver fibrosis if present. Molecular tests for mutations associated with HH are considered the gold standard of current HH testing. Liver biopsy is not needed for diagnosing all patients suspected of having HH, but may be ordered in some cases.

Phlebotomy is considered the treatment of choice for patients with iron overload due to hereditary hemochromatosis (HH). Each unit of blood contains approximately 200 to 250 mg of iron. As erythrocytes are removed by phlebotomy, iron stores are mobilized and utilized in the production of new, circulating erythrocytes. Through periodic phlebotomies, stored iron is removed until iron-deficient erythropoiesis is induced. The initial, or iron reduction, phase of treatment typically consists of removing one unit (450 mL) of whole blood once or twice weekly. Prior to beginning phlebotomy, the patient’s hemoglobin and hematocrit must be checked to ensure that the patient is not anemic. A sample for serum ferritin is also collected at this time.Initial treatment goals include inducing iron deficient hematopoiesis without the development of debilitating symptoms of anemia. A hemoglobin concentration of 10.0 to 12.0 g/dL is often used as a target range. The initial treatment phase continues until excess stored iron is removed and ferritin levels decrease to approximately 50 ng/mL. (13) Ferritin and hemoglobin levels are periodically monitored during this phase. The number of phlebotomies needed to reduce iron levels and induce anemia is related to the degree of initial iron overload. Patients may be referred to a hematologist or gastroenterologist during the initial treatment phase. Many patients receive therapeutic phlebotomy services in a hospital or doctor’s office, but patients may also undergo phlebotomy at a blood center. Blood collected from persons with HH may be used for transfusion or as blood products if it has been collected from a facility with an approved variance from the US Food and Drug Administration. Not all blood centers have applied for or been granted this variance.(14)The initial treatment phase continues until excess stored iron is removed and ferritin levels decrease to approximately 50 ng/mL. Removal of excess stored iron may take from one month to three years.

Lifelong treatment of hereditary hemochromatosis (HH) is needed to keep iron at low levels. Without regular treatment, iron stores will re-accumulate. The primary care physician may manage patient care during long-term maintenance. Long-term maintenance typically consists of removal of an average of 2 to 6 units of whole blood yearly, although this number is variable. Monitoring of hemoglobin and serum ferritin levels determine the frequency of phlebotomy. Serum ferritin levels should be maintained at concentrations of no more than 50 ng/mL. (10,13))

Deferoxamine (DFO), an iron chelating agent, may be used to reduce iron overload in patients for whom phlebotomy is contraindicated or not well tolerated. Examples include patients with sickle cell disease or thalassemia whose anemia would be exacerbated by phlebotomies. DFO is seldom used to treat hereditary hemochromatosis (HH) due to the low cost and efficacy of phlebotomy therapy. DFO is typically administered by intravenous or subcutaneous infusion.Patients with HH may be counseled to avoid alcohol use in order to avoid liver damage. With the exception of iron supplements, dietary restrictions on iron ingestion are rarely advised.

Markely increased stainable iron is present in this biopsy. Iron stores may be increased in sideroblastic anemia, chronic infections, hemochromatosis, hemosiderosis due to numerous blood transfusions, chronic hepatitis, cirrhosis, and uremia.