Beta Thalassemia


Article Author:
Todd Needs


Article Editor:
David Lynch


Editors In Chief:
Chaddie Doerr


Managing Editors:
Avais Raja
Orawan Chaigasame
Carrie Smith
Abdul Waheed
Khalid Alsayouri
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James Hughes
Beata Beatty
Beenish Sohail
Nazia Sadiq
Hajira Basit
Phillip Hynes


Updated:
6/22/2019 12:47:08 PM

Introduction

Thalassemias are a common cause of hypochromic microcytic anemia which arises from the reduced or absent synthesis of the globin chain of hemoglobin. Thalassemias are a quantitative defect of hemoglobin synthesis. This is in contrast with hemoglobinopathies, such as sickle cell disease, which are structural or qualitative defects of hemoglobin. Beta-thalassemia refers to an inherited mutation of the beta-globin gene, causing reduced synthesis of the beta globin chain of hemoglobin. The highest prevalence of beta-thalassemia mutations is in people of Mediterranean, Middle Eastern, and Asian descent. Over 200 different thalassemia-causing mutations have been identified in the beta-globin gene, leading to wide genotypic and phenotypic variability of the disease.[1] The three classifications of beta-thalassemia are defined by their clinical and laboratory findings. Beta-thalassemia minor, also called carrier or trait, is the heterozygous state that is usually asymptomatic with mild anemia. Homozygosity or compound heterozygosity for beta-thalassemia mutations cause a more severe spectrum of anemias called beta-thalassemia intermedia and beta-thalassemia major. These two are distinguished clinically by transfusion dependence. Beta-thalassemia major requires routine transfusions, and intermedia does not.

Laboratory findings suggestive of thalassemia include microcytic anemia with a reference range or increased red blood cell count and a reference range red cell distribution width.  On peripheral smear, red blood cells are hypochromic with increased target cells. There may be significant anisopoikilocytosis (variation of size and shape) in cases of beta-thalassemia major. Exclusion of iron deficiency and hemoglobin electrophoresis or high-performance liquid chromatography are often required for diagnosis. Treatment is primarily with blood transfusion, depending on the degree of anemia. Complications of beta-thalassemia include iron overload and bone-deforming marrow expansion with extramedullary hematopoiesis.

Etiology

Beta-thalassemia is an inherited disorder that is a result of various mutations (over 200 disease-causing mutations have been identified) or, rarely, deletions of the beta-globin gene (HbB) on chromosome 11. These mutations are primarily point mutations that affect transcriptional control, translation, and splicing of the HbB gene and gene product.[1] 

The spectrum of disease severity is due to the bi-allelic inheritance of two copies of the beta-globin gene, one on each chromosome 11, as well as the heterogeneous pool of disease-causing mutations. The genotypic variability of beta globin synthesis is designated beta(+) for decreased production and beta(0) for absent production. The phenotypic variability is designated as either minor, intermedia, or major. Beta-thalassemia minor is heterozygosity with one unaffected beta-globin gene and one affected, either beta(+) or beta(0). Homozygosity or compound heterozygosity with beta(+) or beta(0) causes intermedia and major. These two are distinguished clinically by the severity of anemia and not by genotype.

Epidemiology

The frequency of beta-thalassemia mutations varies by regions of the world with the highest prevalence in the Mediterranean, the Middle-East, and Southeast and Central Asia. The reported carrier prevalence in Greek and Turkish populations in Cyprus is up to 15%.[2] The prevalence also parallels that of malaria as a proposed survival advantage provides the selective pressure for the high carrier frequency in these populations.

Pathophysiology

Hemoglobin is a tetramer of two alpha globin chains combined with two non-alpha globin chains. Fetal hemoglobin (HbF) is the primary hemoglobin until six months of age and consists of two alpha chains and two gamma chains. Adult hemoglobin is primarily hemoglobin A (HbA), consisting of two alpha chains and two beta chains. A smaller component of adult hemoglobin is hemoglobin A2 (HbA2), consisting of two alpha chains and two delta chains. 

The pathogenesis of beta-thalassemia is two-fold. First, there is decreased hemoglobin synthesis causing anemia and an increase in HbF and HbA2 as there are decreased beta chains for HbA formation. Second, and of most pathologic significance in beta-thalassemia major and intermedia, the relative excess alpha chains form insoluble alpha chain inclusions that cause marked intramedullary hemolysis. This ineffective erythropoiesis leads to severe anemia and erythroid hyperplasia with bone marrow expansion and extramedullary hematopoiesis. The bone marrow expansion leads to bony deformities, characteristically of the facial bones which cause frontal bossing and maxillary protrusion. Biochemical signaling from marrow expansion involving the Bone morphogenetic protein (BMP) pathway inhibits hepcidin production causing iron hyperabsorption.[3] Inadequately treated patients and transfusion-dependent patients are at risk for end-organ damaging iron overload. Hepatosplenomegaly from extramedullary hematopoiesis and ongoing hemolysis also causes thrombocytopenia and hepatic dysfunction. 

Beta-thalassemia minor causes microcytosis with, at most, mild anemia as a result of reduced HbA synthesis. Individuals with beta-thalassemia minor have one unaffected beta-globin gene, so they can still produce sufficient hemoglobin to supply the body’s regular demand without causing significant erythroid hyperplasia. Furthermore, the hemoglobin deficit is compensated by an increase in other hemoglobin forms, commonly HbA2.

Beta-thalassemia can also coexist with other hemoglobinopathies (Hemoglobin S, C, and E, for example) and cause variably clinically significant anemias in the heterozygous beta-thalassemia carrier. Delta-beta-thalassemia is clinically similar to beta-thalassemia, and it occurs when there is a deletion of the neighboring delta and beta genes. The pathophysiology of delta-beta-thalassemia parallels that of beta-thalassemia, except there is not an increased HbA2 since the delta chain is also affected.

History and Physical

Beta-thalassemia minor is typically discovered incidentally on routine CBC. Patients may have mild symptoms of anemia without significant physical exam findings. Patients with beta-thalassemia major present between 6 and 24 months of age when hemoglobin production transitions from fetal (HbF) to adult (HbA). Severe anemia ensues and presents as feeding problems, irritability, failure to thrive, pallor, and abdominal enlargement from hepatosplenomegaly. Untreated or undertreated infants, especially in resource-poor areas, will suffer from growth retardation, jaundice, and skeletal deformities from bone marrow expansion. Frontal bossing, maxillary hypertrophy, and long bone deformities are common skeletal findings. Beta-thalassemia intermedia encompasses a wide range of clinical presentations, although, by definition, it is not severe enough to require regular transfusions. Intermedia can present in children as young as two years of age with growth and developmental delay. Milder forms of beta-thalassemia intermedia may first present in adults as fatigue and pallor. Beta-thalassemia intermedia can have variable degrees of physical exam findings suggestive of erythroid hyperplasia and extramedullary hematopoiesis as described for beta-thalassemia major; however, this reactive hematopoiesis is sufficient to compensate for the anemia without requiring transfusion.[4] With longstanding hemolysis, patients with beta-thalassemia major and intermedia can have signs and symptoms of gallbladder disease secondary to gallstone formation.[5][6]

Evaluation

The CBC of a beta-thalassemia patient will show microcytic hypochromic anemia. In beta-thalassemia minor, the red cell number is often elevated, and the red cell distribution width (RDW) will typically show low elevations. The normal to mildly elevated RDW can help differentiate thalassemias from other microcytic hypochromic anemias, such as iron deficiency anemia and sideroblastic anemia where the RDW is typically very high. The peripheral blood smear will show microcytic hypochromic anemia with target cells, teardrop cells, and often coarse basophilic stippling (see Image 1). In severe forms of beta-thalassemia, there is anisopoikilocytosis with bizarre red cell morphology and numerous nucleated red blood cells.

The CBC and peripheral smear findings are non-specific. A diagnosis of beta-thalassemia requires hemoglobin electrophoresis or high-performance liquid chromatography (HPLC) to demonstrate abnormal percentages of HbA, HbA2, and sometimes HbF. The general pattern of beta-thalassemia is a decreased HbA percentage and a mildly increased HbA2; less than 10% with variably increased HbF. A HbA2 above 10% suggests a variant hemoglobin rather than beta-thalassemia. The magnitude of the HbA decrease depends on the genetic makeup of the affected individual. Patients with beta(+) alleles will have variably decreased HbA levels, and those that are homozygous beta(0) will produce no HbA. Beta-thalassemia minor characteristically has increased HbA2 (4-8%) with variably normal-to-low elevations of HbF. Beta-thalassemia major typically shows markedly elevated HbF (30-to-greater than 95%) with normal to mildly elevated HbA2. The distinction between beta-thalassemia major and intermedia is a clinical one and does not have diagnostic laboratory findings.   

A common confounding factor in hemoglobin electrophoresis is a concomitant iron deficiency that masks an underlying beta-thalassemia minor. The resultant electrophoresis pattern appears normal. This is because iron deficiency anemia normalizes the HbA2 percentage that is the key finding in beta-thalassemia minor. Other causes of elevated HbA2 other than thalassemia include antiretroviral therapy, vitamin B12/folate deficiency, and hyperthyroidism. Hemoglobin electrophoresis and high-performance liquid chromatography can also elucidate other hemoglobinopathies complicating a beta-thalassemia trait.

Treatment / Management

As thalassemia minor is a carrier state, it is typically asymptomatic. Genetic counseling and prenatal diagnosis might be indicated when carriers are detected. Thalassemia major is treated with red blood cell transfusion. The aim of transfusion is mainly to suppress erythroid expansion. It also serves to mitigate symptoms of anemia and to inhibit gastrointestinal iron absorption. Severe anemia and growth delays are indications for transfusions as well as clinical signs of erythroid expansion including facial changes, bony expansion, and splenomegaly. The goal hemoglobin level for most transfusion regimens is a pretransfusion hemoglobin of 9 to 10 g/dL and posttransfusion hemoglobin of 13 to 14 g/dL.[7] Regular transfusions put patients at risk of iron overload, transfusion reactions, and also to developing red cell antibodies which makes finding suitable donor blood for subsequent transfusions difficult. Bone marrow transplant and cord blood transplant offer the only potential cure for beta-thalassemia.[8] In patients without pre-transplant complications of clinical progression of the disease, stem cell transplantation of HLA-identical siblings has a disease-free survival rate over 90%. Cord blood transplant is a consideration for parents who already have a child with beta-thalassemia and later identify an HLA-compatible fetus in a subsequent pregnancy.[9]

The iron status of routinely transfused patients must be monitored. Clinical signs of iron overload (e.g., hypogonadism, hypothyroidism, hypoparathyroidism, diabetes, liver fibrosis, heart dysfunction) and serial serum ferritin remain the most reliable method to evaluate iron overload. Iron chelation therapy is generally started after patients have received 10 to 20 transfusions or have serum ferritin levels > 1000 ng/mL. Other nutritional sequelae of thalassemia include relative folate deficiency, calcium depletion, and vitamin C deficiency.[5] Symptomatic hypersplenism is common in thalassemia intermedia and major and may be treated with splenectomy. Post-splenectomy patients have an increased susceptibility to blood-borne infections with encapsulated bacteria and should receive appropriate immunizations.

Differential Diagnosis

The major differential diagnosis in hypochromic microcytic anemia is either iron deficiency anemia or a hemoglobinopathy.  Iron deficiency is easily ruled out with reference range iron studies (serum iron, total iron binding capacity, percent transferrin saturation). Hemoglobinopathies typically require hemoglobin electrophoresis or HPLC for diagnosis.  Alpha thalassemia will show normal.

Enhancing Healthcare Team Outcomes

Clinically significant beta-thalassemia presents in childhood, making it a familiar diagnosis for all clinicians providing pediatric care. While the pediatrician or family practice provider may be the first to discover a hematologic abnormality, coordination with an interprofessional team comprising hematologists, pathologists, and nurses familiar with beta-thalassemia is necessary for optimal diagnosis and management. Care plans may include nutrition counseling and exercise consultation.[10][11] [Level 2]


  • Image 6803 Not availableImage 6803 Not available
    Contributed by David T. Lynch, MD and Todd R. Needs, DO
Attributed To: Contributed by David T. Lynch, MD and Todd R. Needs, DO

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Beta Thalassemia - Questions

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Beta thalassemia occurs due to which of the following?



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A 7-month-old infant presents with prominent facial features, failure to thrive, and enlarged spleen on physical exam. His hemoglobin is found to be 5.6 grams/dL. Which of the following laboratory values is also expected?



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A 9-month-old infant presents with a gradual onset of decreased appetite, pallor, and poor weight gain. Physical examination reveals hepatosplenomegaly. A CBC shows a severe microcytic, hypochromic anemia with target cells and frequent nucleated red cells on the blood smear. The lead level and iron studies are within reference ranges. What is the best next test to order?



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Which of the following treatment-related complications is expected to occur in a child with beta thalassemia after several years?



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A routine CBC at performed on a patient that is 1 year of age shows a mild microcytic anemia. Hemoglobin electrophoresis shows increased hemoglobin A2. What is the most likely diagnosis?



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An adult woman of Mediterranean descent has asymptomatic anemia discovered on routine lab testing. Which of the following lab values is most supportive of a diagnosis of beta thalassemia?



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A 25-year-old woman of Iranian descent returns to the clinic for followup labs after being treated for iron deficiency anemia. Her previous workup included hemoglobin electrophoresis that was normal. Today, a repeat CBC shows mild microcytic anemia. Ferritin level is within the reference range. What is the next best step in management?



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Which of the following is a characteristic finding on peripheral smear of beta-thalassemia?



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Which of the following most accurately describes the etiology of beta-thalassemia?



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Beta Thalassemia - References

References

Karimi M,Cohan N,De Sanctis V,Mallat NS,Taher A, Guidelines for diagnosis and management of Beta-thalassemia intermedia. Pediatric hematology and oncology. 2014 Oct     [PubMed]
Matta BN,Musallam KM,Maakaron JE,Koussa S,Taher AT, A killer revealed: 10-year experience with beta-thalassemia intermedia. Hematology (Amsterdam, Netherlands). 2014 Jun     [PubMed]
Cao A,Galanello R, Beta-thalassemia. Genetics in medicine : official journal of the American College of Medical Genetics. 2010 Feb     [PubMed]
Ashiotis T,Zachariadis Z,Sofroniadou K,Loukopoulos D,Stamatoyannopoulos G, Thalassaemia in Cyprus. British medical journal. 1973 Apr 7     [PubMed]
Frazer DM,Wilkins SJ,Darshan D,Badrick AC,McLaren GD,Anderson GJ, Stimulated erythropoiesis with secondary iron loading leads to a decrease in hepcidin despite an increase in bone morphogenetic protein 6 expression. British journal of haematology. 2012 Jun     [PubMed]
Galanello R,Origa R, Beta-thalassemia. Orphanet journal of rare diseases. 2010 May 21     [PubMed]
Schrier SL,Angelucci E, New strategies in the treatment of the thalassemias. Annual review of medicine. 2005     [PubMed]
Muncie HL Jr,Campbell J, Alpha and beta thalassemia. American family physician. 2009 Aug 15     [PubMed]
Gaziev J,Lucarelli G, Stem cell transplantation for hemoglobinopathies. Current opinion in pediatrics. 2003 Feb     [PubMed]
Molazem Z,Noormohammadi R,Dokouhaki R,Zakerinia M,Bagheri Z, The Effects of Nutrition, Exercise, and a Praying Program on Reducing Iron Overload in Patients With Beta-Thalassemia Major: A Randomized Clinical Trial. Iranian journal of pediatrics. 2016 Oct     [PubMed]
Mirhosseini NZ,Shahar S,Ghayour-Mobarhan M,Banihashem A,Kamaruddin NA,Hatef MR,Esmaili HA, Bone-related complications of transfusion-dependent beta thalassemia among children and adolescents. Journal of bone and mineral metabolism. 2013 Jul     [PubMed]

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