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AUTHOR AND EDITOR INFORMATION

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Author: Alexandra C Cheerva, MD, Associate Professor of Pediatrics, Hematology/Oncology Division, University of Louisville; Consulting Staff, Section of Pediatric Hematology and Oncology, Kosair Children's Hospital

Alexandra C Cheerva is a member of the following medical societies: American Society for Blood and Marrow Transplantation, American Society of Clinical Oncology, American Society of Pediatric Hematology/Oncology, Children's Oncology Group, and Kentucky Medical Association

Coauthor(s): Ashok Raj, MD, Assistant Professor, Section of Pediatric Hematology and Oncology, Department of Pediatrics, Kosair Children's Hospital, University of Louisville

Editors: Gary R Jones, MD, Associate Medical Director, Clinical Development, Berlex Laboratories; Mary L Windle, PharmD, Adjunct Assistant Professor, University of Nebraska Medical Center College of Pharmacy, Pharmacy Editor, eMedicine.com, Inc; Gary D Crouch, MD, Program Director of Pediatric Hematology-Oncology Fellowship, Department of Pediatrics, Associate Professor, Uniformed Services University of the Health Sciences; Helen SL Chan, MBBS, FRCP(C), FAAP, Senior Scientist, Research Institute; Professor, Division of Hematology/Oncology, Department of Pediatrics, The Hospital for Sick Children, University of Toronto, Canada; Max J Coppes, MD, PhD, MBA, Executive Director, Center for Cancer and Blood Disorders, Children's National Medical Center, Washington, DC; Professor of Medicine, Oncology, and Pediatrics, Georgetown University

Author and Editor Disclosure

Synonyms and related keywords: hemoglobin H disease, alpha-thalassemia syndrome, α-thalassemia syndrome, HbH disease, chronic hemolytic anemia, genetic disorder, thalassemia, anemia, alpha-globin gene, globin protein, malaria protection, alpha-globin chains, jaundice, hepatosplenomegaly, folic acid deficiency, iron deficiency

INTRODUCTION

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Background

Thalassemia is one of the world's most common single-gene disorders. The hallmark of the thalassemia syndromes is decreased or absent synthesis of one or more globin chains. a-Thalassemia is the decreased production of a2-globin or a1-globin gene products. Individuals with thalassemia syndrome are most often of African, Asian, Mediterranean, or Middle Eastern descent. Mutations and gene deletions causing the thalassemia genotype have arisen independently in different populations but then have propagated by means of natural selection. Thus, the thalassemias are more prevalent in regions in which malaria is endemic because the red blood cell phenotype confers some protection against malaria. However, individuals with b-thalassemia syndromes have somewhat better protection against malaria.

Pathophysiology

The a-thalassemia syndromes are a group of hereditary anemias of varying clinical severity. They are caused by deficient expression in one or more of the two a-globin genes on chromosome 16 and are characterized by the absence or reduced synthesis of a-globin chains. Healthy individuals have 2 a-globin genes on each chromosome 16 (aa/aa).

The loss of one (-a) or both (--) of these cis-linked genes is the most common cause of the a-thalassemias. Patients with hemoglobin H (HbH) disease have lost 3 of the a-globin genes (--/-a), and these individuals have chronic hemolytic anemia of variable severity. Fetuses with hydrops fetalis (--/--) die either in utero or shortly after birth because of severe anemia. Individuals with 3 functional a-globin genes (-a/aa) are silent carriers and are clinically and hematologically healthy.

Two genotypes (--/aa and -a/-a) are associated with the a-thalassemia trait. The genotypes are termed either the cis form if both a2-globin and a1-globin genes are deleted on the same chromosome (--/aa) or the trans form if the 2 a2-globin genes of both alleles of chromosome 16 are deleted but the a1-globin genes are intact (-a/-a).

In both cases, 2 a-globin genes are inactivated. The (--SEA) type of a-thalassemia deletion removes both a-globin genes in cis, is common in Southeast Asia, and is the most common cause for HbH disease and hydrops fetalis in that part of the world. Nondeletional forms of a-thalassemia in which the a-globin genes are intact are caused by mutations similar to those causing b-thalassemia and are relatively uncommon.

HbH disease usually is observed in individuals from Southeast Asia who have deletions of both a-globin genes on one allele and a deletion of only one a-globin gene on the other allele. The deletions result in HbH (b4) characterized by a high b-globin–a-globin synthetic ratio and a 2- to 5-fold excess in b-globin production. The excess b chains aggregate into tetramers, which account for 5-30% of the hemoglobin (Hb) level in patients with HbH disease.

HbH has a high affinity for oxygen and has no Bohr effect or heme-heme interaction; therefore, HbH ineffectively supplies oxygen to the tissues under physiologic conditions. Patients with significant amounts of HbH have a defect in oxygen-carrying capacity that is more severe than that expected on the basis of the Hb concentration. Red cells containing HbH are sensitive to oxidative stress; thus, they may be more susceptible to hemolysis when oxidants such as sulfonamides are administered. Aging erythrocytes contain more precipitated HbH than younger erythrocytes; therefore, aging erythrocytes are removed from the circulation prematurely. Thus, HbH disease is primarily a hemolytic disorder. When bone marrow cells are examined, HbH inclusions are rare, and erythropoiesis is apparently effective. Erythroid hyperplasia can result in typical structural bone abnormalities with marrow hyperplasia, bone thinning, maxillary hyperplasia, and pathologic fractures.

Frequency

United States

Frequency of a-thalassemia is low among Caucasians. Among African Americans, the frequency of the a-thalassemia trait is relatively high (20-30%), but the trait usually consists of the loss of only a single a-globin gene on each allele, and HbH disease is rare. In North America, many multicultural communities are growing, and these populations have increased frequencies of thalassemia syndromes.

In some ethnic groups, such as the Southeast Asian population, in particular, and Mediterranean populations, HbH and Hb Bart (g4) disease are common because of the frequent co-inheritance of one allele lacking both a-globin genes and the other allele lacking one a-globin gene. The high frequency of Hb Constant Spring in the Southeast Asian population can lead to the HbH (--/-aCS) phenotype, which involves an elongated form of a-globin.

International

a-Thalassemia is perhaps the most common single-gene disorder in the world. The frequency of a-thalassemia alleles is 5-10% in persons from the Mediterranean basin, 20-30% in portions of West Africa, and as high as 60-80% in parts of Saudi Arabia, India, Thailand, Papua New Guinea, and Melanesia. In Thailand, which has a population of 62 million people, approximately 7000 infants are born each year with HbH disease. The frequency of heterozygote carrier status among the Chinese population has been reported to vary from 5-15%. The frequency of a-thalassemia is less than 0.01% in Great Britain, Iceland, and Japan.

Mortality/Morbidity

The degree of anemia varies, and morbidity and mortality are largely related to the degree. In some families, a syndrome of HbH disease and varying degrees of mental retardation has been reported. As a result of multiple blood transfusions, consequences of iron overload on the heart, liver, and other organs may be present, and these can contribute to morbidity and mortality.

Race

a-Thalassemia occurs in individuals of all ethnic backgrounds but particularly those of African, Asian, Central American, Mediterranean, and Middle Eastern descent. Emigration from regions in which carrier frequency is high increases the presence of thalassemia syndromes in other parts of the world. Indeed, the disorders are increasing in frequency in North America and Europe.

Sex

Males and females are affected equally.

Age

HbH disease occurs in persons of all ages. Neonates with HbH disease often have anemia, with severely hypochromic red blood cells, and high levels of Hb Bart (g4). This is in contrast to neonates with b-chain disease, who often have no anemia, although they may have hypochromic red blood cells. This is because a-chains are required for production of all forms of Hb, while b-chains are found only in the adult form of Hb, hemoglobin A (HbA). In the fetus and neonate, most Hb is hemoglobin F (HbF), which is composed of 2 a- and 2 g-chains.


CLINICAL

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History

Symptoms are consistent with a chronic hemolytic anemia and include episodes of severe pallor and anemia. Infections, fever, ingestion of oxidative compounds, or drug use may precipitate hemolytic episodes, and patients may require transfusions. Generally, HbH disease is thought to be a mild disorder. However, because of the marked variability in degree of anemia, patients may range from asymptomatic to needing periodic transfusions to having severe anemia with hepatomegaly and splenomegaly. Some patients may also suffer hydrops fetalis syndrome in utero. Pregnancy may also be a special circumstance, in which patients may develop severe anemia and require transfusions.

Physical

Findings at physical examination are consistent with those of chronic hemolytic anemia and include pallor, jaundice, hepatosplenomegaly, folic acid deficiency, pigment gallstones, leg ulcers, and increased susceptibility to infection.

Causes

The disorder is inherited in a complex autosomal recessive manner; therefore, males and females are affected equally. Individuals with deletions of one or two a-globin genes have no clinical manifestations, while individuals with deletions of all 4 a-globin genes usually die in utero of hydrops fetalis.


DIFFERENTIALS

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Anemia, Acute
Anemia, Chronic
Thalassemia
Thalassemia Intermedia

Other Problems to be Considered

Autoimmune hemolytic anemia
Nonimmune hemolytic anemia
Iron deficiency anemia
Hydrops fetalis


WORKUP

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Lab Studies

  • CBC and reticulocyte counts: Moderately severe hemolytic anemia is present, with hypochromia and microcytosis. Often, mild-to-moderate reticulocytosis is present. The higher the reticulocyte count, the more severe the hemolysis.
  • Hb electrophoresis: Results indicate the presence of HbH, as well as typical findings of adult HbA, HbA2, and HbF concentrations.
  • Serum iron, total iron binding capacity, and ferritin analysis: Exclude iron deficiency, since it may be present in patients with thalassemia. In the setting of undiagnosed disease, iron deficiency also can cause microcytosis, which must be excluded. In older patients or in individuals who have received transfusions, monitor ferritin levels closely. Once the ferritin level is greater than 1000 ng/mL, consider beginning chelation therapy with deferoxamine. Iron deficiency may result in a misleading hemoglobin electropheresis finding due to suppression of hemoglobin production.
  • Newer DNA-based techniques using polymerase chain reaction (PCR) may be used for globin-chain analysis. The techniques can be helpful in some cases in which both the patient's and parents' a-chain configurations are elucidated exactly, which can be useful in predicting the risk that a couple's future offspring will be affected.

Imaging Studies

  • Ultrasound: Sonographs of the liver, gallbladder, and spleen frequently detect gallstones, which consist of pigment resulting from hemolysis. Hepatomegaly was present in 70% of 502 patients in Thailand, 60% of 153 patients in Sardinia, and 14% of 88 patients in Taiwan. Splenomegaly is also common in HbH disease and was found in 79% of patients in Thailand, 60% in Sardinia, and 47% in Taiwan.


TREATMENT

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Medical Care

  • General supportive care: Transfusions may be needed periodically or in periods of severe anemia, such as during parvovirus infections. Usually, patients with HbH disease live fairly normal lives and require few transfusions. Hb levels usually range from 7-10 g/dL. Transfusion therapy is reserved for patients with severe anemia (usually <7 g/dL) and symptomatic anemia. Hemolytic episodes may be triggered either by drug use or by infection. The use of special red blood cell units (eg, washed, irradiated, leucocyte depleted) usually is not required.
  • Carefully document iron deficiency with laboratory testing prior to the administration of supplemental iron. Many patients with apparent iron deficiency can have iron overload (hemachromatosis), the effects of which can contribute to morbidity and mortality.
  • In very severe cases, allogeneic bone marrow transplantation may be considered, which is curative, since the hematopoietic system of the patient is replaced by that of the donor. A sibling who is fully matched for human leukocyte antigen (HLA) and who is, at most, a carrier for a-thalassemia (deletion of 2 a-globin genes) is the most suitable donor. However, because of the toxicity of the procedure, bone marrow transplantation should be limited to the most severely affected patients.

Surgical Care

Splenectomy may be beneficial in some patients. Usually, splenectomy is reserved for patients with symptoms of hypersplenism, as reflected by leukopenia, thrombocytopenia, and worsening anemia or, in patients who were previously stable, development of a transfusion requirement.

Consultations

Patients with HbH disease usually undergo close follow-up monitoring by a hematologist who can coordinate care and treat the patient during acute hemolytic and anemic episodes.

Diet

In patients with elevated ferritin levels, the diet should be low in iron.


MEDICATION

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In general, no medications are needed; however, if the reticulocyte count is elevated, supplement the diet with folic acid. If a patient has an elevated ferritin level, consider chelation therapy with deferoxamine.

Drug Category: Vitamins

This is a supplement with folic acid, a vitamin necessary for red blood cell production.

Drug NameFolic acid (Folvite)
DescriptionNecessary coenzyme for nucleoprotein synthesis and maintenance in patients with erythropoiesis.
Adult Dose1-3 mg/d PO/IV/IM/SC
Pediatric Dose0-12 months: 0.5-1 mg/d PO/IV/IM/SC
1-10 years: Up to 1 mg/d PO/IV/IM/SC
>11 years: Administer as in adults
ContraindicationsDocumented hypersensitivity
InteractionsIncrease in seizure frequency and subtherapeutic levels with concurrent phenytoin
PregnancyA - Safe in pregnancy
PrecautionsPregnancy category C if >0.8 mg/d; benzyl alcohol may be present as preservative and is associated with fatal gasping syndrome in premature infants; resistance to treatment may occur in patients with alcoholism and other vitamin deficiencies

Drug Category: Chelation agents

Iron overload (usually from multiple transfusions) may require chelation therapy, which usually begins when the ferritin level is greater than 1000 ng/mL.

Drug NameDeferoxamine mesylate (Desferal)
DescriptionFreely soluble in water. Approximately 8 mg of iron is bound by 100 mg of deferoxamine. Excreted in urine and bile and discolors the urine red. Readily chelates iron from ferritin and hemosiderin but not transferrin. Most effective when provided to the circulation continuously by means of infusion. May be administered by IM injection, slow infusion, SC bolus, or continuous infusion. Does not effectively chelate other trace metals of nutritional importance.
Adult DoseAcute iron intoxication: 1 g IM followed by 500 mg 4 h and 8 h later; may repeat with 500 mg IM q4-12h; not to exceed 6 g/d
Alternative: 1 g IV at a rate not exceeding 15 mg/kg/h followed by 500 mg q4h for 2 doses; administer additional IV infusion slowly over 24 h; not to exceed 6 g/d
Pediatric Dose<3 years: Not established
>3 years:
IM: 50 mg/kg IM initially; not to exceed 1 g/dose; may repeat with half dose 4h and 8h later; similar IM doses can be administered at q4h for next 24 h if clinical findings warrant
IV: 20 mg/kg IV initially over 1-2 min followed by an infusion of 60 mg/kg over 6-8 h; rapid injection can cause hypotension; if clinically indicated, additional therapy can be administered
IM in most circumstances
SC: 20-50 mg/kg/d SC continuous infusion over 8-12 h; not to exceed 2 g/d
ContraindicationsDocumented hypersensitivity; absence of acute iron poisoning; severe renal disease and anuria (consider dose reduction after loading dose)
InteractionsConcomitant administration with prochlorperazine can cause transient loss of consciousness
PregnancyC - Safety for use during pregnancy has not been established.
PrecautionsTachycardia, hypotension, and shock may occur with chronic therapy (can increase cardiovascular collapse due to iron toxicity); adverse effects in GI tract include abdominal discomfort, nausea, vomiting, and diarrhea (may increase symptoms of acute iron toxicity); flushing; fever; rapid IV injection can cause hypotension

Drug NameDeferasirox (Exjade)
DescriptionTab for oral susp. Oral iron chelation agent demonstrated to reduce liver iron concentration in adults and children who receive repeated RBC transfusions. Binds iron with high affinity in a 2:1 ratio. Approved to treat chronic iron overload due to multiple blood transfusions. Treatment initiation recommended with evidence of chronic iron overload (ie, transfusion of about 100 mL/kg packed RBCs [about 20 U for 40-kg person] and serum ferritin level consistently >1000 mcg/L).
Adult DoseInitial: 20 mg/kg PO qd on empty stomach 30 min ac; calculate dose to nearest whole tablet
Maintenance: Adjust dose by 5- to 10-mg/kg/d increments q3-6mo according to serum ferritin level trends; not to exceed 30 mg/kg/d
Note: Dissolve tab completely in water, orange juice, or apple juice, then immediately drink susp; resuspend any remaining residue in small volume of liquid and swallow
Pediatric Dose<2 years: Not established
>2 years: Administer as in adults
ContraindicationsDocumented hypersensitivity
InteractionsData limited; do not take with aluminum-containing antacids
PregnancyC - Safety for use during pregnancy has not been established.
PrecautionsCommon adverse effects include diarrhea, nausea, abdominal pain, headache, pyrexia, cough, and rash; may increase serum creatinine and hepatic enzyme levels; decrease dose with persistent elevation of serum creatinine level; may cause auditory and visual disturbances; slight decreases in serum copper and zinc levels may occur; dissolve tab completely in water, orange juice, or apple juice and drink resulting susp immediately (do not swallow tab whole, do not chew or crush); measure serum ferritin levels monthly and adjust dose q3-6mo based on serum ferritin trends


FOLLOW-UP

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Further Outpatient Care

  • Pay close attention to iron overload in patients. Even patients who have not received a large number of transfusions may have elevated total body iron loads and may require chelation therapy.

Deterrence/Prevention

  • Prenatal testing is available for families at risk (eg, parents are members of ethnic groups with the highest carrier rates). Globin-chain analysis can be performed by means of PCR testing.
  • Although neonatal screening is not sufficient in the diagnosis HbH disease, patients with the disease at birth have large amounts of Hb Bart (g4), which is detectable with neonatal screening.

Prognosis

  • The risk of severe anemia and the need for transfusions are lifelong.

Patient Education

  • Educate patients and their parents regarding HbH disease.
  • Genetic counseling is important for parents of a child with HbH disease. Parents must understand the risk that future children may have HbH disease and other, possibly more severe, thalassemia syndromes.


MISCELLANEOUS

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Medical/Legal Pitfalls

  • Failure to recognize this type of anemia as a genetic condition and to properly inform parents and patients of the potential to have children with HbH disease or other thalassemia syndromes
  • Failure to confirm iron deficiency anemia using laboratory testing in a patient with HbH disease may lead to continuation of supplemental iron therapy for an extended period (usually >3 mo), which may lead to secondary hemachromatosis. If iron overload continues longer than 1-2 years, it can lead to damage in multiple organs, including cardiac, hepatic, and endocrine dysfunction.

Special Concerns

  • Pregnancy: During pregnancy, iron and folic acid deficiencies can alter the mean corpuscular volume (MCV). As a result, thalassemia may be difficult to diagnose or exclude during pregnancy. If a strong suspicion exists and if a definitive answer is required, PCR should be performed for globin-chain analysis. Pregnant women with HbH disease require special care, because those women with severe anemia may have serious health problems during their pregnancy and this may adversely affect the health of their fetuses. The incidence of low birth weight is also high in women with HbH disease and severe anemia.
  • Geriatric patients: A particularly severe acquired form of HbH disease may occur in elderly men with clonal myeloproliferative diseases. In these patients, HbH levels may be as high as 60%. Extremely low a-chain–b-chain synthetic ratios may be present, and low a-globin messenger RNA levels are found in bone marrow cells. Hemolytic disease caused by HbH disease may wax and wane with the course of the myeloproliferative disease.
  • a-thalassemia/mental retardation (ATR) syndromes:
    • In the ATR-16 syndrome, affected children have chromosomal rearrangements involving the short arm of chromosome 16 telomere, which includes the a-globin complex. This results in monosomy for the 16p telomere, and the a-thalassemia phenotype. If an affected child also inherits a single a-globin gene deletion from the other parent, HbH disease results. These children may also have mental retardation and other congenital anomalies thought to be due to deletions of dose-sensitive genes on chromosome 16p.
    • The ATR-X syndrome is an X-linked disorder caused by mutations of the ATRX gene located on chromosome Xq13.3. It is more frequent than the ATR-16 syndrome. Males who are affected usually have severe intellectual and physical handicaps and other congenital anomalies. Skeletal deformities are present in up to 90% of patients. The a-thalassemia phenotype is variable, with HbH inclusion bodies found in 0-32% of circulating erythrocytes.


ACKNOWLEDGMENTS

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The authors and editors of eMedicine gratefully acknowledge the contributions of previous author Afshin Ameri, MD to the development and writing of this article.


REFERENCES

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Hemoglobin H Disease excerpt

Article Last Updated: Jul 19, 2006