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Beta thalassemia

January 01, 1970

Beta thalassemias (β thalassemias) are a group of inherited blood disorders. They are forms of thalassemia caused by reduced or absent synthesis of the beta chains of hemoglobin that result in variable outcomes ranging from severe anemia to clinically asymptomatic individuals. Global annual incidence is estimated at one in 100,000.[4] Beta thalassemias occur due to malfunctions in the hemoglobin subunit beta or HBB. The severity of the disease depends on the nature of the mutation.[5]

Beta-thalassemia
Other namesMicrocytemia, beta type[1]
Beta thalassemia genetics, the picture shows one example of how beta thalassemia is inherited. The beta globin gene is located on chromosome 11. A child inherits two beta globin genes (one from each parent).
SpecialtyHematology
TypesThalassemia minor, intermediate and major[2]
CausesMutations in the HBB gene[1]
Diagnostic methodDNA analysis[3]
TreatmentDepends on type (see types)

HBB blockage over time leads to decreased beta-chain synthesis. The body's inability to construct new beta-chains leads to the underproduction of HbA (adult hemoglobin).[6] Reductions in HbA available overall to fill the red blood cells in turn leads to microcytic anemia. Microcytic anemia ultimately develops in respect to inadequate HBB protein for sufficient red blood cell functioning.[7] Due to this factor, the patient may require blood transfusions to make up for the blockage in the beta-chains. [citation needed] Repeated blood transfusions cause severe problems associated with iron overload.[8]

Signs and symptoms edit

 
The hand of a person with severe anemia (left, wearing ring) compared to one without

Three main forms have been described: thalassemia minor, thalassemia intermedia, and thalassemia major which vary from asymptomatic or mild symptoms to severe anemia requiring lifelong transfusions.[9] Individuals with beta thalassemia major (those who are homozygous for thalassemia mutations, or inheriting 2 mutations) usually present within the first two years of life with symptomatic severe anemia, poor growth, and skeletal abnormalities. Untreated thalassemia major eventually leads to death, usually by heart failure; therefore, prenatal screening is very important.[10] Those with beta thalassemia intermedia (those who are compound heterozygotes for the beta thalassemia mutation) usually present later in life with mild to moderate symptoms of anemia.[9] Beta thalassemia trait (also known as beta thalassemia minor) involves heterozygous inheritance of a beta-thalassemia mutation and patients usually have borderline microcytic, hypochromic anemia and they are usually asymptomatic or have mild symptoms.[9] Beta thalassemia minor can also present as beta thalassemia silent carriers; those who inherit a beta thalassemic mutation but have no hematologic abnormalities nor symptoms.[9] Some people with thalassemia are susceptible to health complications that involve the spleen (hypersplenism) and gallstones (due to hyperbilirubinemia from peripheral hemolysis).[9][1] These complications are mostly found in thalassemia major and intermedia patients.[citation needed]

Excess iron (from hemolysis or transfusions) causes serious complications within the liver, heart, and endocrine glands. Severe symptoms include liver cirrhosis, liver fibrosis, and in extreme cases, liver cancer.[11] Heart failure, growth impairment, diabetes and osteoporosis are life-threatening conditions which can be caused by beta thalassemia major.[12] The main cardiac abnormalities seen as a result of beta thalassemia and iron overload include left ventricular systolic and diastolic dysfunction, pulmonary hypertension, valvulopathy, arrhythmias, and pericarditis. Increased gastrointestinal iron absorption is seen in all grades of beta thalassemia, and increased red blood cell destruction by the spleen due to ineffective erythropoiesis further releases additional iron into the bloodstream.[13]

Additional symptoms of beta thalassemia major or intermedia include the classic symptoms of moderate to severe anemia including fatigue, growth and developmental delay in childhood, leg ulcers and organ failure.[9] Ineffective erythropoiesis (red blood cell production) can also lead to compensatory bone marrow expansion which can then lead to bony changes/deformities, bone pain and craniofacial abnormalities.[9] Extramedullary organs such as the liver and spleen that can also undergo erythropoiesis become activated leading to hepatosplenomegaly (enlargement of the liver and spleen).[9] Other tissues in the body can also become sites of erythropoiesis, leading to extramedullary hematopoietic pseudotumors which may cause compressive symptoms if they occur in the thoracic cavity or spinal canal.[9]

Cause edit

Mutations edit

Two major groups of mutations can be distinguished:

  • Nondeletion forms: These defects, in general, involve a single base substitution or small insertions near or upstream of the β globin gene. Most often, mutations occur in the promoter regions preceding the beta-globin genes. Less often, abnormal splice variants are believed to contribute to the disease.[14]
  • Deletion forms: Deletions of different sizes involving the β globin gene produce different syndromes such as (βo) or hereditary persistence of fetal hemoglobin syndromes.[15]

Mutations are characterized as (βo) if they prevent any formation of β globin chains, mutations are characterized as (β+) if they allow some β globin chain formation to occur.[9]

Name Older synonyms Description Alleles
Thalassemia minor   Heterozygous form: Only one of β globin alleles bears a mutation. Affected individuals will develop microcytic anemia. Detection usually involves lower than normal mean corpuscular volume value (<80 fL).[16] β+
βo
Thalassemia intermedia   Affected individuals can often manage a normal life but may need occasional transfusions, e.g., at times of illness or pregnancy, depending on the severity of their anemia.[17] β++
βo+
Thalassemia major Mediterranean anemia; Cooley anemia Homozygous form: Occurs when both alleles have thalassemia mutations. This is a severe microcytic, hypochromic anemia. Untreated, it causes anemia, splenomegaly and severe bone deformities, and progresses to death before age 20. Treatment consists of periodic blood transfusion; splenectomy for splenomegaly and chelation of transfusion-related iron overload.[18] βoo

mRNA assembly edit

 
Protein HBB PDB 1a00. This is a healthy beta globin protein.

Beta thalassemia is a hereditary disease affecting hemoglobin. As with about half of all hereditary diseases,[19] an inherited mutation damages the assembly of the messenger-type RNA (mRNA) that is transcribed from a chromosome. DNA contains both the instructions (genes) for stringing amino acids together into proteins, as well as stretches of DNA that play important roles in regulating produced protein levels.[20]

In thalassemia, an additional, contiguous length or a discontinuous fragment of non-coding instructions is included in the mRNA. This happens because the mutation obliterates the boundary between the intronic and exonic portions of the DNA template.[21] Because all the coding sections may still be present, normal hemoglobin may be produced and the added genetic material, if it produces pathology, instead disrupts regulatory functions enough to produce anemia. Hemoglobin's normal alpha and beta subunits each have an iron-containing central portion (heme) that allows the protein chain of a subunit to fold around it. Normal adult hemoglobin contains 2 alpha and 2 beta subunits.[22] Thalassemias typically affect only the mRNAs for production of the beta chains (hence the name). Since the mutation may be a change in only a single base (single-nucleotide polymorphism), on-going efforts seek gene therapies to make that single correction.[23][24]

Risk factors edit

Family history and ancestry are factors that increase the risk of beta thalassemia. Depending on family history, if a person's parents or grandparents had beta thalassemia major or intermedia, there is a 75% (3 out of 4) probability (see inheritance chart at top of page) of the mutated gene being inherited by an offspring. Even if a child does not have beta thalassemia major or intermedia, they can still be a carrier, possibly resulting in future generations of their offspring having beta thalassemia.[citation needed]

Another risk factor is ancestry. Beta thalassemia occurs most often in people of Italian, Greek, Middle Eastern, Southern Asian, and African ancestry.[25]

Diagnosis edit

 
Peripheral blood smear from a person with beta thalassemia. The red blood cells vary greatly in shape and size and some look empty because of their low hemoglobin content (Giemsa stain).

Abdominal pain due to hypersplenism, splenic infarction and right-upper quadrant pain caused by gallstones are major clinical manifestations. However, diagnosing thalassemia from symptoms alone is inadequate. Physicians note these signs as associative due to this disease's complexity.[26] The following associative signs can attest to the severity of the phenotype: pallor, poor growth, inadequate food intake, splenomegaly, jaundice, maxillary hyperplasia, dental malocclusion, cholelithiasis, systolic ejection murmur in the presence of severe anemia and pathologic fractures. Based on symptoms, tests are ordered for a differential diagnosis. These tests include complete blood count; hemoglobin electrophoresis; serum transferrin, ferritin, total iron-binding capacity; urine urobilin and urobilogen; peripheral blood smear, which may show codocytes, or target cells;[27] hematocrit; and serum bilirubin.[28][29] The expected pattern on hemoglobin electrophoresis in people with beta-thalassemia is an increased level of hemoglobin A2 and slightly increased hemoglobin F.[citation needed] The diagnosis is confirmed with hemoglobin electrophoresis or high performance liquid chromatography.[9]

Skeletal changes associated with expansion of the bone marrow:

  • Chipmunk facies: bossing of the skull, prominent malar eminence, depression of the bridge of the nose, tendency to a slant of the eye, and exposure of the upper teeth due to hypertrophy of the maxillae.[30]
  • Hair-on-end (or "crew cut") on skull X-ray: new bone formation due to the inner table. [citation needed]

DNA analysis edit

All beta thalassemias may exhibit abnormal red blood cells; a family history is followed by DNA analysis.[3] This test is used to investigate deletions and mutations in the alpha- and beta-globin-producing genes. Family studies can be done to evaluate carrier status and the types of mutations present in other family members. DNA testing is not routine, but can help diagnose thalassemia and determine carrier status. In most cases the treating physician uses a clinical prediagnosis assessing anemia symptoms: fatigue, breathlessness and poor exercise tolerance.[31] Further genetic analysis may include HPLC should routine electrophoresis prove difficult.[28]

Prevention edit

Beta thalassemia is a hereditary disease allowing for a preventative treatment by carrier screening and prenatal diagnosis. It can be prevented if one parent has normal genes, giving rise to screenings that empower carriers to select partners with normal hemoglobin. A study aimed at detecting the genes that could give rise to offspring with sickle cell disease. Patients diagnosed with beta thalassemia have MCH ≤ 26 pg and an RDW < 19. Of 10,148 patients, 1,739 patients had a hemoglobin phenotype and RDW consistent with beta thalassemia. After the narrowing of patients, the HbA2 levels were tested presenting 77 patients with beta thalassemia.[32] This screening procedure proved insensitive in populations of West African ancestry because of the indicators has high prevalence of alpha thalassemia. Countries have programs distributing information about the reproductive risks associated with carriers of haemoglobinopathies. Thalassemia carrier screening programs have educational programs in schools, armed forces, and through mass media as well as providing counseling to carriers and carrier couples.[33] Screening has shown reduced incidence; by 1995 the prevalence in Italy reduced from 1:250 to 1:4000, and a 95% decrease in that region. The decrease in incidence has benefitted those affected with thalassemia, as the demand for blood has decreased, therefore improving the supply of treatment.[citation needed]

Treatment edit

Beta thalassemia major edit

 
Surgically removed spleen of a thalassemic child. It is about 15 times larger than normal.

Affected children require regular lifelong blood transfusions. Bone marrow transplants can be curative for some children.[34] Patients receive frequent blood transfusions that lead to or potentiate iron overload.[35] Iron chelation treatment is necessary to prevent damage to internal organs in cases of iron overload. Advances in iron chelation treatments allow patients with thalassemia major to live long lives with access to proper treatment. Popular chelators include deferoxamine and deferiprone.[36][37]

The oral chelator deferasirox was approved for use in 2005 in some countries.[38][39] Bone marrow transplantation is the only cure and is indicated for patients with severe thalassemia major. Transplantation can eliminate a patient's dependence on transfusions. Absent a matching donor, a savior sibling can be conceived by preimplantation genetic diagnosis (PGD) to be free of the disease as well as to match the recipient's human leukocyte antigen (HLA) type.[40]

Serum ferritin (the storage form of iron) is routinely measured in those with beta thalassemia to determine the degree of iron overload; with increased ferritin levels directing the use of iron chelation therapy. The three iron chelators; subcutaneous deferoxamine, oral deferiprone and oral deferasirox can be used as monotherapy or in combination, they have all been shown to decrease serum/systemic iron levels, hepatic and cardiac iron levels as well as decreasing the risk of cardiac arrhythmia, heart failure and death.[9] Hepatic and myocardial MRI is also used to quantify the iron deposition in target organs, especially the heart and liver, to guide therapy.[9]

Scientists at Weill Cornell Medical College have developed a gene therapy strategy that could feasibly treat both beta-thalassemia and sickle cell disease. The technology is based on delivery of a lentiviral vector carrying both the human β-globin gene and an ankyrin insulator to improve gene transcription and translation, and boost levels of β-globin production.[41]

On June 10, 2022, a U.S. federal advisory panel recommended that the FDA approve a gene therapy treatment for use with beta thalassemia.[42] The manufacturer Bluebird bio charges $2.8 million in the United States for its one-time treatment Zynteglo (betibeglogene autotemcel).[43][44]

Gene editing therapies aimed at increasing fetal hemoglobin production in beta thalassemia as well as sickle cell anemia by inhibiting the BCL11A gene are also being explored.[45][46]

Surgical edit

Patients with thalassemia major are more inclined to have a splenectomy. The use of splenectomies have been declining in recent years due to decreased prevalence of hypersplenism in adequately transfused patients. Splenectomy is also associated with increased risk of infections and increased morbidity due to vascular disease, as the spleen is involved in scavenging to rid the body of pathologic or abnormal red blood cells.[9] Patients with hypersplenism are more likely to have a lower amount of healthy blood cells in their body than normal and reveal symptoms of anemia. The different surgical techniques are the open and laparoscopic method.[2] The laparoscopic method requires longer operating time but a shorter recovery period with a smaller and less prominent surgical scar. If it is unnecessary to remove the entire spleen a partial splenectomy may occur; this method preserves some of the immune function while reducing the probability of hypersplenism. Those undergoing splenectomy should receive an appropriate pneumococcal vaccine at least one week (preferably three weeks) before the surgery.[47]

Therapeutic edit

Long-term transfusion therapy (in those with transfusion dependent beta thalassemia) is a treatment used to maintain hemoglobin levels at a target pre-transfusion hemoglobin level of 9–10.5 g/dL (11–12 g/dL in those with concomitant heart disease).[9] To ensure quality blood transfusions, the packed red blood cells should be leucoreduced. By having leucoreduced blood packets, the patient is at a lower risk to develop adverse reactions by contaminated white cells and preventing platelet alloimmunisation.[48] Patients with allergic transfusion reactions or unusual red cell antibodies must receive washed red cells or cryopreserved red cells. Washed red cells have been removed of plasma proteins that would have become a target of the patient's antibodies allowing the transfusion to be carried out safely. Cryopreserved red cells are used to maintain a supply of rare donor units for patients with unusual red cell antibodies or missing common red cell antigens. These regular transfusions promote normal growth, physical activities and suppress bone marrow hyperactivity.[citation needed]

Pharmaceutical edit

During normal iron homeostasis the circulating iron is bound to transferrin. But with iron overload (such as with frequent blood transfusions), the ability for transferrin to bind iron is exceeded and non-transferrin bound iron accumulated. This unbound iron is toxic due to its high propensity to induce oxygen species and is responsible for cellular damage. The prevention of iron overload protects patients from morbidity and mortality. The primary aim is to bind to and remove iron from the body and a rate equal to the rate of transfusional iron input or greater than iron input.[49] Iron chelation is a medical therapy that may prevent the complications of iron overload.[9] Every unit of transfused blood contains 200–250 mg of iron and the body has no natural mechanism to remove excess iron. The excess iron can be removed by iron chelators (deferoxamine, deferiprone and deferasirox).[50]

Luspatercept (ACE-536) is a recombinant fusion protein that is used as a treatment in adults with transfusion dependent beta thalassemia. It consists of a modified extra-cellular domain of human activin receptor type IIB bound to the Fc portion of the human IgG1 antibody.[9] The molecule binds to select transforming growth factor beta superfamily ligands to block SMAD2 and 3 signaling, thus enhancing erythroid maturation.[9] The medication has been shown to reduce the transfusion burden by 33% in adults with transfusion dependent beta thalassemia as compared to placebo and was also associated with decreased ferritin levels (with no significant decreases in liver or cardiac iron levels).[9]

Exagamglogene autotemcel was approved for medical use in the United Kingdom in November 2023.[51][52]

Beta thalassemia intermedia edit

Patients with beta thalassemia intermedia require no transfusions or may require episodic blood transfusions during certain circumstances (infection, pregnancy, surgery).[9] Patients with frequent transfusions may develop iron overload and require chelation therapy.[53] Transmission is autosomal recessive; however, dominant mutations and compound heterozygotes have been reported. Genetic counseling is recommended and prenatal diagnosis may be offered.[54]

Beta thalassemia minor edit

Patients with beta thalassemia minor are usually asymptomatic and are often monitored without treatment.[9] Beta thalassemia minor may coexist with other conditions such as chronic hepatitis B, chronic hepatitis C, non-alcoholic fatty liver disease and alcoholic liver disease that, when combined or co-existing, may cause a person to have iron overload of the liver and more severe liver disease.[55]

Epidemiology edit

The beta form of thalassemia is particularly prevalent among the Mediterranean peoples and this geographical association is responsible for its naming: thalassa (θάλασσα) is the Greek word for sea and haima (αἷμα) is the Greek word for blood.[56][57][citation needed] In Europe, the highest concentrations of the disease are found in Greece and the Turkish coastal regions. The major Mediterranean islands (except the Balearics) such as Sicily, Sardinia, Corsica, Cyprus, Malta and Crete are heavily affected in particular.[58][59] Other Mediterranean peoples, as well as those in the vicinity of the Mediterranean, also have high incidence rates, including people from West Asia and North Africa. The data indicate that 15% of the Greek and Turkish Cypriots are carriers of beta-thalassaemia genes, while 10% of the population carry alpha-thalassaemia genes.[60]

Evolutionary adaptation edit

The thalassemia trait may confer a degree of protection against malaria,[61] which is or was prevalent in the regions where the trait is common, thus conferring a selective survival advantage on carriers (known as heterozygous advantage), thus perpetuating the mutation. In that respect, the various thalassemias resemble another genetic disorder affecting hemoglobin, sickle-cell disease.[62]

Incidence edit

The disorder is more prevalent in certain ethnicities and age groups. Beta thalassemia is most prevalent in the "thalassemia belt" which includes areas in Sub-Saharan Africa, the Mediterranean extending into the Middle East and Southeast Asia.[9] This geographical distribution is thought to be due to beta-thalassemia carrier state (beta thalassemia minor) conferring a resistance to malaria.[9] In the United States, thalassemia's prevalence is approximately 1 in 272,000 or 1,000 people. There have been 4,000 hospitalized cases in England in 2002 and 9,233 consultant episodes for thalassemia. Men accounted for 53% of hospital consultant episodes and women accounted for 47%. The mean patient age is 23, with only 1% of consultants being older than 75, and 69% being 15–59. It is estimated that 1.5% of the world's population are carriers and 40,000 affected infants are born with the disease annually.[9] Beta thalassemia major is usually fatal in infancy if blood transfusions are not initiated immediately.[63]

See also edit

References edit

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  52. ^ "Vertex and CRISPR Therapeutics Announce Authorization of the First CRISPR/Cas9 Gene-Edited Therapy, Casgevy (exagamglogene autotemcel), by the United Kingdom MHRA for the Treatment of Sickle Cell Disease and Transfusion-Dependent Beta Thalassemia" (Press release). Vertex Pharmaceuticals. 16 November 2023. from the original on 22 November 2023. Retrieved 9 December 2023 – via Business Wire.
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  55. ^ Brissot P, Cappellini MD (2014). "Liver Disease". In Cappellini MD, Cohen A, Porter J, Taher A, Viprakasit V (eds.). Guidelines for the Management of Transfusion Dependent Thalassaemia (3rd ed.). Thalassaemia International Federation. pp. 609–11, 637. ISBN 9789963717064. PMID 2561094. from the original on 2022-06-17. Retrieved 2023-12-09.
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  62. ^ Weatherall, David J (2010). "The Thalassemias: Disorders of Globin Synthesis". In Lichtman, MA; Kipps, TJ; Seligsohn, U; Kaushansky, K; Prchal, JT (eds.). Williams Hematology (8 ed.). The McGraw-Hill Companies. from the original on 2013-11-04. Retrieved 2012-10-02.
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Further reading edit

  • Cao, Antonio; Galanello, Renzo (2010). "Beta-Thalassemia". In Pagon, Roberta A; Bird, Thomas D; Dolan, Cynthia R; Stephens, Karen; Adam, Margaret P (eds.). GeneReviews. University of Washington, Seattle. PMID 20301599.
  • Bahal, Raman; McNeer, Nicole Ali; Quijano, Elias; Liu, Yanfeng; Sulkowski, Parker; Turchick, Audrey; Lu, Yi-Chien; Bhunia, Dinesh C.; Manna, Arunava; Greiner, Dale L.; Brehm, Michael A.; Cheng, Christopher J.; López-Giráldez, Francesc; Ricciardi, Adele; Beloor, Jagadish; Krause, Diane S.; Kumar, Priti; Gallagher, Patrick G.; Braddock, Demetrios T.; Saltzman, W. Mark; Ly, Danith H.; Glazer, Peter M. (26 October 2016). "In vivo correction of anaemia in β-thalassemic mice by γPNA-mediated gene editing with nanoparticle delivery". Nature Communications. 7: 13304. Bibcode:2016NatCo...713304B. doi:10.1038/ncomms13304. ISSN 2041-1723. PMC 5095181. PMID 27782131.

External links edit

 
Scholia has a topic profile for Beta thalassemia.

January 01, 1970
beta, thalassemia, thalassemias, group, inherited, blood, disorders, they, forms, thalassemia, caused, reduced, absent, synthesis, beta, chains, hemoglobin, that, result, variable, outcomes, ranging, from, severe, anemia, clinically, asymptomatic, individuals,. Beta thalassemias b thalassemias are a group of inherited blood disorders They are forms of thalassemia caused by reduced or absent synthesis of the beta chains of hemoglobin that result in variable outcomes ranging from severe anemia to clinically asymptomatic individuals Global annual incidence is estimated at one in 100 000 4 Beta thalassemias occur due to malfunctions in the hemoglobin subunit beta or HBB The severity of the disease depends on the nature of the mutation 5 Beta thalassemiaOther namesMicrocytemia beta type 1 Beta thalassemia genetics the picture shows one example of how beta thalassemia is inherited The beta globin gene is located on chromosome 11 A child inherits two beta globin genes one from each parent SpecialtyHematologyTypesThalassemia minor intermediate and major 2 CausesMutations in the HBB gene 1 Diagnostic methodDNA analysis 3 TreatmentDepends on type see types HBB blockage over time leads to decreased beta chain synthesis The body s inability to construct new beta chains leads to the underproduction of HbA adult hemoglobin 6 Reductions in HbA available overall to fill the red blood cells in turn leads to microcytic anemia Microcytic anemia ultimately develops in respect to inadequate HBB protein for sufficient red blood cell functioning 7 Due to this factor the patient may require blood transfusions to make up for the blockage in the beta chains citation needed Repeated blood transfusions cause severe problems associated with iron overload 8 Contents 1 Signs and symptoms 2 Cause 2 1 Mutations 2 2 mRNA assembly 3 Risk factors 4 Diagnosis 4 1 DNA analysis 5 Prevention 6 Treatment 6 1 Beta thalassemia major 6 1 1 Surgical 6 1 2 Therapeutic 6 1 3 Pharmaceutical 6 2 Beta thalassemia intermedia 6 3 Beta thalassemia minor 7 Epidemiology 7 1 Evolutionary adaptation 7 2 Incidence 8 See also 9 References 10 Further reading 11 External linksSigns and symptoms edit nbsp The hand of a person with severe anemia left wearing ring compared to one without Three main forms have been described thalassemia minor thalassemia intermedia and thalassemia major which vary from asymptomatic or mild symptoms to severe anemia requiring lifelong transfusions 9 Individuals with beta thalassemia major those who are homozygous for thalassemia mutations or inheriting 2 mutations usually present within the first two years of life with symptomatic severe anemia poor growth and skeletal abnormalities Untreated thalassemia major eventually leads to death usually by heart failure therefore prenatal screening is very important 10 Those with beta thalassemia intermedia those who are compound heterozygotes for the beta thalassemia mutation usually present later in life with mild to moderate symptoms of anemia 9 Beta thalassemia trait also known as beta thalassemia minor involves heterozygous inheritance of a beta thalassemia mutation and patients usually have borderline microcytic hypochromic anemia and they are usually asymptomatic or have mild symptoms 9 Beta thalassemia minor can also present as beta thalassemia silent carriers those who inherit a beta thalassemic mutation but have no hematologic abnormalities nor symptoms 9 Some people with thalassemia are susceptible to health complications that involve the spleen hypersplenism and gallstones due to hyperbilirubinemia from peripheral hemolysis 9 1 These complications are mostly found in thalassemia major and intermedia patients citation needed Excess iron from hemolysis or transfusions causes serious complications within the liver heart and endocrine glands Severe symptoms include liver cirrhosis liver fibrosis and in extreme cases liver cancer 11 Heart failure growth impairment diabetes and osteoporosis are life threatening conditions which can be caused by beta thalassemia major 12 The main cardiac abnormalities seen as a result of beta thalassemia and iron overload include left ventricular systolic and diastolic dysfunction pulmonary hypertension valvulopathy arrhythmias and pericarditis Increased gastrointestinal iron absorption is seen in all grades of beta thalassemia and increased red blood cell destruction by the spleen due to ineffective erythropoiesis further releases additional iron into the bloodstream 13 Additional symptoms of beta thalassemia major or intermedia include the classic symptoms of moderate to severe anemia including fatigue growth and developmental delay in childhood leg ulcers and organ failure 9 Ineffective erythropoiesis red blood cell production can also lead to compensatory bone marrow expansion which can then lead to bony changes deformities bone pain and craniofacial abnormalities 9 Extramedullary organs such as the liver and spleen that can also undergo erythropoiesis become activated leading to hepatosplenomegaly enlargement of the liver and spleen 9 Other tissues in the body can also become sites of erythropoiesis leading to extramedullary hematopoietic pseudotumors which may cause compressive symptoms if they occur in the thoracic cavity or spinal canal 9 Cause editMutations edit Two major groups of mutations can be distinguished Nondeletion forms These defects in general involve a single base substitution or small insertions near or upstream of the b globin gene Most often mutations occur in the promoter regions preceding the beta globin genes Less often abnormal splice variants are believed to contribute to the disease 14 Deletion forms Deletions of different sizes involving the b globin gene produce different syndromes such as bo or hereditary persistence of fetal hemoglobin syndromes 15 Mutations are characterized as bo if they prevent any formation of b globin chains mutations are characterized as b if they allow some b globin chain formation to occur 9 Name Older synonyms Description Alleles Thalassemia minor Heterozygous form Only one of b globin alleles bears a mutation Affected individuals will develop microcytic anemia Detection usually involves lower than normal mean corpuscular volume value lt 80 fL 16 b bbo b Thalassemia intermedia Affected individuals can often manage a normal life but may need occasional transfusions e g at times of illness or pregnancy depending on the severity of their anemia 17 b b bo b Thalassemia major Mediterranean anemia Cooley anemia Homozygous form Occurs when both alleles have thalassemia mutations This is a severe microcytic hypochromic anemia Untreated it causes anemia splenomegaly and severe bone deformities and progresses to death before age 20 Treatment consists of periodic blood transfusion splenectomy for splenomegaly and chelation of transfusion related iron overload 18 bo bo mRNA assembly edit nbsp Protein HBB PDB 1a00 This is a healthy beta globin protein Beta thalassemia is a hereditary disease affecting hemoglobin As with about half of all hereditary diseases 19 an inherited mutation damages the assembly of the messenger type RNA mRNA that is transcribed from a chromosome DNA contains both the instructions genes for stringing amino acids together into proteins as well as stretches of DNA that play important roles in regulating produced protein levels 20 In thalassemia an additional contiguous length or a discontinuous fragment of non coding instructions is included in the mRNA This happens because the mutation obliterates the boundary between the intronic and exonic portions of the DNA template 21 Because all the coding sections may still be present normal hemoglobin may be produced and the added genetic material if it produces pathology instead disrupts regulatory functions enough to produce anemia Hemoglobin s normal alpha and beta subunits each have an iron containing central portion heme that allows the protein chain of a subunit to fold around it Normal adult hemoglobin contains 2 alpha and 2 beta subunits 22 Thalassemias typically affect only the mRNAs for production of the beta chains hence the name Since the mutation may be a change in only a single base single nucleotide polymorphism on going efforts seek gene therapies to make that single correction 23 24 Risk factors editFamily history and ancestry are factors that increase the risk of beta thalassemia Depending on family history if a person s parents or grandparents had beta thalassemia major or intermedia there is a 75 3 out of 4 probability see inheritance chart at top of page of the mutated gene being inherited by an offspring Even if a child does not have beta thalassemia major or intermedia they can still be a carrier possibly resulting in future generations of their offspring having beta thalassemia citation needed Another risk factor is ancestry Beta thalassemia occurs most often in people of Italian Greek Middle Eastern Southern Asian and African ancestry 25 Diagnosis edit nbsp Peripheral blood smear from a person with beta thalassemia The red blood cells vary greatly in shape and size and some look empty because of their low hemoglobin content Giemsa stain Abdominal pain due to hypersplenism splenic infarction and right upper quadrant pain caused by gallstones are major clinical manifestations However diagnosing thalassemia from symptoms alone is inadequate Physicians note these signs as associative due to this disease s complexity 26 The following associative signs can attest to the severity of the phenotype pallor poor growth inadequate food intake splenomegaly jaundice maxillary hyperplasia dental malocclusion cholelithiasis systolic ejection murmur in the presence of severe anemia and pathologic fractures Based on symptoms tests are ordered for a differential diagnosis These tests include complete blood count hemoglobin electrophoresis serum transferrin ferritin total iron binding capacity urine urobilin and urobilogen peripheral blood smear which may show codocytes or target cells 27 hematocrit and serum bilirubin 28 29 The expected pattern on hemoglobin electrophoresis in people with beta thalassemia is an increased level of hemoglobin A2 and slightly increased hemoglobin F citation needed The diagnosis is confirmed with hemoglobin electrophoresis or high performance liquid chromatography 9 Skeletal changes associated with expansion of the bone marrow Chipmunk facies bossing of the skull prominent malar eminence depression of the bridge of the nose tendency to a slant of the eye and exposure of the upper teeth due to hypertrophy of the maxillae 30 Hair on end or crew cut on skull X ray new bone formation due to the inner table citation needed DNA analysis edit All beta thalassemias may exhibit abnormal red blood cells a family history is followed by DNA analysis 3 This test is used to investigate deletions and mutations in the alpha and beta globin producing genes Family studies can be done to evaluate carrier status and the types of mutations present in other family members DNA testing is not routine but can help diagnose thalassemia and determine carrier status In most cases the treating physician uses a clinical prediagnosis assessing anemia symptoms fatigue breathlessness and poor exercise tolerance 31 Further genetic analysis may include HPLC should routine electrophoresis prove difficult 28 Prevention editBeta thalassemia is a hereditary disease allowing for a preventative treatment by carrier screening and prenatal diagnosis It can be prevented if one parent has normal genes giving rise to screenings that empower carriers to select partners with normal hemoglobin A study aimed at detecting the genes that could give rise to offspring with sickle cell disease Patients diagnosed with beta thalassemia have MCH 26 pg and an RDW lt 19 Of 10 148 patients 1 739 patients had a hemoglobin phenotype and RDW consistent with beta thalassemia After the narrowing of patients the HbA2 levels were tested presenting 77 patients with beta thalassemia 32 This screening procedure proved insensitive in populations of West African ancestry because of the indicators has high prevalence of alpha thalassemia Countries have programs distributing information about the reproductive risks associated with carriers of haemoglobinopathies Thalassemia carrier screening programs have educational programs in schools armed forces and through mass media as well as providing counseling to carriers and carrier couples 33 Screening has shown reduced incidence by 1995 the prevalence in Italy reduced from 1 250 to 1 4000 and a 95 decrease in that region The decrease in incidence has benefitted those affected with thalassemia as the demand for blood has decreased therefore improving the supply of treatment citation needed Treatment editBeta thalassemia major edit nbsp Surgically removed spleen of a thalassemic child It is about 15 times larger than normal Affected children require regular lifelong blood transfusions Bone marrow transplants can be curative for some children 34 Patients receive frequent blood transfusions that lead to or potentiate iron overload 35 Iron chelation treatment is necessary to prevent damage to internal organs in cases of iron overload Advances in iron chelation treatments allow patients with thalassemia major to live long lives with access to proper treatment Popular chelators include deferoxamine and deferiprone 36 37 The oral chelator deferasirox was approved for use in 2005 in some countries 38 39 Bone marrow transplantation is the only cure and is indicated for patients with severe thalassemia major Transplantation can eliminate a patient s dependence on transfusions Absent a matching donor a savior sibling can be conceived by preimplantation genetic diagnosis PGD to be free of the disease as well as to match the recipient s human leukocyte antigen HLA type 40 Serum ferritin the storage form of iron is routinely measured in those with beta thalassemia to determine the degree of iron overload with increased ferritin levels directing the use of iron chelation therapy The three iron chelators subcutaneous deferoxamine oral deferiprone and oral deferasirox can be used as monotherapy or in combination they have all been shown to decrease serum systemic iron levels hepatic and cardiac iron levels as well as decreasing the risk of cardiac arrhythmia heart failure and death 9 Hepatic and myocardial MRI is also used to quantify the iron deposition in target organs especially the heart and liver to guide therapy 9 Scientists at Weill Cornell Medical College have developed a gene therapy strategy that could feasibly treat both beta thalassemia and sickle cell disease The technology is based on delivery of a lentiviral vector carrying both the human b globin gene and an ankyrin insulator to improve gene transcription and translation and boost levels of b globin production 41 On June 10 2022 a U S federal advisory panel recommended that the FDA approve a gene therapy treatment for use with beta thalassemia 42 The manufacturer Bluebird bio charges 2 8 million in the United States for its one time treatment Zynteglo betibeglogene autotemcel 43 44 Gene editing therapies aimed at increasing fetal hemoglobin production in beta thalassemia as well as sickle cell anemia by inhibiting the BCL11A gene are also being explored 45 46 Surgical edit Patients with thalassemia major are more inclined to have a splenectomy The use of splenectomies have been declining in recent years due to decreased prevalence of hypersplenism in adequately transfused patients Splenectomy is also associated with increased risk of infections and increased morbidity due to vascular disease as the spleen is involved in scavenging to rid the body of pathologic or abnormal red blood cells 9 Patients with hypersplenism are more likely to have a lower amount of healthy blood cells in their body than normal and reveal symptoms of anemia The different surgical techniques are the open and laparoscopic method 2 The laparoscopic method requires longer operating time but a shorter recovery period with a smaller and less prominent surgical scar If it is unnecessary to remove the entire spleen a partial splenectomy may occur this method preserves some of the immune function while reducing the probability of hypersplenism Those undergoing splenectomy should receive an appropriate pneumococcal vaccine at least one week preferably three weeks before the surgery 47 Therapeutic edit Long term transfusion therapy in those with transfusion dependent beta thalassemia is a treatment used to maintain hemoglobin levels at a target pre transfusion hemoglobin level of 9 10 5 g dL 11 12 g dL in those with concomitant heart disease 9 To ensure quality blood transfusions the packed red blood cells should be leucoreduced By having leucoreduced blood packets the patient is at a lower risk to develop adverse reactions by contaminated white cells and preventing platelet alloimmunisation 48 Patients with allergic transfusion reactions or unusual red cell antibodies must receive washed red cells or cryopreserved red cells Washed red cells have been removed of plasma proteins that would have become a target of the patient s antibodies allowing the transfusion to be carried out safely Cryopreserved red cells are used to maintain a supply of rare donor units for patients with unusual red cell antibodies or missing common red cell antigens These regular transfusions promote normal growth physical activities and suppress bone marrow hyperactivity citation needed Pharmaceutical edit During normal iron homeostasis the circulating iron is bound to transferrin But with iron overload such as with frequent blood transfusions the ability for transferrin to bind iron is exceeded and non transferrin bound iron accumulated This unbound iron is toxic due to its high propensity to induce oxygen species and is responsible for cellular damage The prevention of iron overload protects patients from morbidity and mortality The primary aim is to bind to and remove iron from the body and a rate equal to the rate of transfusional iron input or greater than iron input 49 Iron chelation is a medical therapy that may prevent the complications of iron overload 9 Every unit of transfused blood contains 200 250 mg of iron and the body has no natural mechanism to remove excess iron The excess iron can be removed by iron chelators deferoxamine deferiprone and deferasirox 50 Luspatercept ACE 536 is a recombinant fusion protein that is used as a treatment in adults with transfusion dependent beta thalassemia It consists of a modified extra cellular domain of human activin receptor type IIB bound to the Fc portion of the human IgG1 antibody 9 The molecule binds to select transforming growth factor beta superfamily ligands to block SMAD2 and 3 signaling thus enhancing erythroid maturation 9 The medication has been shown to reduce the transfusion burden by 33 in adults with transfusion dependent beta thalassemia as compared to placebo and was also associated with decreased ferritin levels with no significant decreases in liver or cardiac iron levels 9 Exagamglogene autotemcel was approved for medical use in the United Kingdom in November 2023 51 52 Beta thalassemia intermedia edit Patients with beta thalassemia intermedia require no transfusions or may require episodic blood transfusions during certain circumstances infection pregnancy surgery 9 Patients with frequent transfusions may develop iron overload and require chelation therapy 53 Transmission is autosomal recessive however dominant mutations and compound heterozygotes have been reported Genetic counseling is recommended and prenatal diagnosis may be offered 54 Beta thalassemia minor edit Patients with beta thalassemia minor are usually asymptomatic and are often monitored without treatment 9 Beta thalassemia minor may coexist with other conditions such as chronic hepatitis B chronic hepatitis C non alcoholic fatty liver disease and alcoholic liver disease that when combined or co existing may cause a person to have iron overload of the liver and more severe liver disease 55 Epidemiology editThe beta form of thalassemia is particularly prevalent among the Mediterranean peoples and this geographical association is responsible for its naming thalassa 8alassa is the Greek word for sea and haima aἷma is the Greek word for blood 56 57 citation needed In Europe the highest concentrations of the disease are found in Greece and the Turkish coastal regions The major Mediterranean islands except the Balearics such as Sicily Sardinia Corsica Cyprus Malta and Crete are heavily affected in particular 58 59 Other Mediterranean peoples as well as those in the vicinity of the Mediterranean also have high incidence rates including people from West Asia and North Africa The data indicate that 15 of the Greek and Turkish Cypriots are carriers of beta thalassaemia genes while 10 of the population carry alpha thalassaemia genes 60 Evolutionary adaptation edit The thalassemia trait may confer a degree of protection against malaria 61 which is or was prevalent in the regions where the trait is common thus conferring a selective survival advantage on carriers known as heterozygous advantage thus perpetuating the mutation In that respect the various thalassemias resemble another genetic disorder affecting hemoglobin sickle cell disease 62 Incidence edit The disorder is more prevalent in certain ethnicities and age groups Beta thalassemia is most prevalent in the thalassemia belt which includes areas in Sub Saharan Africa the Mediterranean extending into the Middle East and Southeast Asia 9 This geographical distribution is thought to be due to beta thalassemia carrier state beta thalassemia minor conferring a resistance to malaria 9 In the United States thalassemia s prevalence is approximately 1 in 272 000 or 1 000 people There have been 4 000 hospitalized cases in England in 2002 and 9 233 consultant episodes for thalassemia Men accounted for 53 of hospital consultant episodes and women accounted for 47 The mean patient age is 23 with only 1 of consultants being older than 75 and 69 being 15 59 It is estimated that 1 5 of the world s population are carriers and 40 000 affected infants are born with the disease annually 9 Beta thalassemia major is usually fatal in infancy if blood transfusions are not initiated immediately 63 See also editAlpha thalassemia Anisopoikilocytosis Delta thalassemia HemoglobinopathyReferences edit a b c Beta thalassemia Genetics Home Reference Archived from the original on 2015 05 13 Retrieved 2015 05 26 a b Advani Pooja Beta Thalassemia Treatment amp Management Medscape Archived from the original on 4 April 2017 Retrieved 4 April 2017 a b McKinney Emily Slone James Susan R Murray Sharon Smith Nelson Kristine Ashwill Jean 2014 04 17 Maternal Child Nursing Elsevier Health Sciences ISBN 9780323293778 Archived from the original on 2023 01 14 Retrieved 2020 10 25 Galanello Renzo Origa Raffaella 21 May 2010 Beta thalassemia Orphanet J Rare Dis 5 11 doi 10 1186 1750 1172 5 11 PMC 2893117 PMID 20492708 Goldman Lee Schafer Andrew I 2015 04 21 Goldman Cecil Medicine Expert Consult Online Elsevier Health Sciences ISBN 9780323322850 Carton James 2012 02 16 Oxford Handbook of Clinical Pathology OUP Oxford ISBN 9780191629938 Archived from the original on 2023 01 14 Retrieved 2020 10 25 Perkin Ronald M Newton Dale A Swift James D 2008 Pediatric Hospital Medicine Textbook of Inpatient Management Lippincott Williams amp Wilkins ISBN 9780781770323 Galanello Renzo Origa Raffaella 2010 05 21 Beta thalassemia Orphanet Journal of Rare Diseases 5 1 11 doi 10 1186 1750 1172 5 11 ISSN 1750 1172 PMC 2893117 PMID 20492708 a b c d e f g h i j k l m n o p q r s t u v w x Taher Ali T Musallam Khaled M Cappellini M Domenica 25 February 2021 b Thalassemias New England Journal of Medicine 384 8 727 743 doi 10 1056 NEJMra2021838 PMID 33626255 S2CID 232049825 Introduction to Pathology for the Physical Therapist Assistant Jones amp Bartlett Publishers 2011 ISBN 9780763799083 Archived from the original on 2023 01 14 Retrieved 2020 10 25 Anderson Gregory J McLaren Gordon D 2012 01 16 Iron Physiology and Pathophysiology in Humans Springer Science amp Business Media ISBN 9781603274845 Archived from the original on 2023 01 14 Retrieved 2020 10 25 Barton James C Edwards Corwin Q Phatak Pradyumna D Britton Robert S Bacon Bruce R 2010 07 22 Handbook of Iron Overload Disorders Cambridge University Press ISBN 9781139489393 Archived from the original on 2023 01 14 Retrieved 2020 10 25 McCance Kathryn L Huether Sue E 2013 12 13 Pathophysiology The Biologic Basis for Disease in Adults and Children Elsevier Health Sciences ISBN 9780323088541 Leonard Debra G B 2007 11 25 Molecular Pathology in Clinical Practice Springer Science amp Business Media ISBN 9780387332277 Archived from the original on 2023 01 14 Retrieved 2020 10 25 Bowen Juan M Mazzaferri Ernest L 2012 12 06 Contemporary Internal Medicine Clinical Case Studies Springer Science amp Business Media ISBN 9781461567134 Disorders National Organization for Rare 2003 NORD Guide to Rare 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Publishers ISBN 9781612331928 Archived from the original on 2023 01 14 Retrieved 2020 10 25 Weatherall David J 2010 The Thalassemias Disorders of Globin Synthesis In Lichtman MA Kipps TJ Seligsohn U Kaushansky K Prchal JT eds Williams Hematology 8 ed The McGraw Hill Companies Archived from the original on 2013 11 04 Retrieved 2012 10 02 Thalassemia Genetic Blood Disorder Expected To Double In Next Few Decades ScienceDaily Archived from the original on 4 April 2017 Retrieved 4 April 2017 Further reading editCao Antonio Galanello Renzo 2010 Beta Thalassemia In Pagon Roberta A Bird Thomas D Dolan Cynthia R Stephens Karen Adam Margaret P eds GeneReviews University of Washington Seattle PMID 20301599 Bahal Raman McNeer Nicole Ali Quijano Elias Liu Yanfeng Sulkowski Parker Turchick Audrey Lu Yi Chien Bhunia Dinesh C Manna Arunava Greiner Dale L Brehm Michael A Cheng Christopher J Lopez Giraldez Francesc Ricciardi Adele Beloor Jagadish Krause Diane S Kumar Priti Gallagher Patrick G Braddock Demetrios T Saltzman W Mark Ly Danith H Glazer Peter M 26 October 2016 In vivo correction of anaemia in b thalassemic mice by gPNA mediated gene editing with nanoparticle delivery Nature Communications 7 13304 Bibcode 2016NatCo 713304B doi 10 1038 ncomms13304 ISSN 2041 1723 PMC 5095181 PMID 27782131 External links edit nbsp Scholia has a topic profile for Beta thalassemia Retrieved from https en wikipedia org w index php title Beta thalassemia amp oldid 1221234031 Thalassemia major, wikipedia, wiki, book, books, library,

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