Diamond-Blackfan anemia overview

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Overview

Historical Perspective

Pathophysiology

Causes

Differentiating Diamond-Blackfan anemia from other Diseases

Epidemiology and Demographics

Risk Factors

Natural History, Complications and Prognosis

Diagnosis

History and Symptoms

Physical Examination

Laboratory Findings

Electrocardiogram

Chest X Ray

CT

MRI

Echocardiography or Ultrasound

Other Imaging Findings

Other Diagnostic Studies

Treatment

Medical Therapy

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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]Associate Editor(s)-in-Chief: Roghayeh Marandi
Synonyms and keywords: Erythrogenesis imperfecta; congenital pure red cell aplasia, hereditary pure red cell aplasia, familial pure red cell aplasia, RP: Ribosomal proteins, RPS: small ribosomal subunit, RPL: large ribosomal subunit, DBA: Diamond-Blackfan anemia

Overview

Diamond-Blackfan anemia(DBA) is a congenital erythroid aplasia that usually presents in infancy.The classic form is characterized by a profound normochromic and usually macrocytic anemia with normal leukocytes and platelets. About half of the affected patients have congenital malformations, and growth retardation in 30% of affected individuals. The symptoms and physical findings associated with DBA vary greatly from person to person. The hematologic complications occur in 90% of affected individuals during the first year of life.

Historical Prespective

Diamond and Blackfan described congenital hypoplastic anemia in 1938. In 1951, responsiveness to corticosteroids was reported. In 1961, Diamond and colleagues presented longitudinal data on 30 patients and noted an association with skeletal abnormalities. In 1997 a region on chromosome 19 was determined to carry a gene mutated in DBA. In 1999, mutations in the ribosomal protein S19 gene (RPS19) were found to be associated with disease in some of the patients. In 2001, it was determined that a second DBA gene lies in a region of chromosome 8. In 2007, Furthermore, mutations in large ribosomal subunit-associated proteins rpl5, rpl11, and rpl35a, have been described. In 2010, 10 additional DBA genes are identified. The Non-RP gene, GATA1, was identified in 2012. Researchers still want to know why steroids often work in DBA, find more mutations, and address some questions about Diamond-Blackfan anemia.

Pathophysiology

The exact pathogenesis of DBA is "Ribosomapathy". Mutations in ribosomal protein genes have been confirmed to be the direct cause of faulty erythropoiesis and anemia. Mutations reduce the actual numbers of ribosomes in blood precursor cells. Without enough ribosomes, the precursors can’t produce enough GATA1, so mature red cells never form. Other blood cells — like platelets, T cells, and B cells — are not affected since they’re not dependent on GATA1. Based on a documented pathogenetic hypothesis that has been named "ribosomal stress", ultimately a defective ribosome biosynthesis leads to apoptosis in those defective erythroid progenitors which in turn is leading to erythroid failure. In "ribosomal stress", reduced RP synthesis activates p53 that induces the downstream events and leads to cell cycle termination or apoptosis, leading to erythroid failure.

Causes

Diamond-Blackfan anemia is caused by heterozygous mutation in a gene encoding a small (RPS7, RPS10, RPS15A, RPS17, RPS19, RPS20, RPS24, RPS26, RPS27, RPS28, RPS29) or large (RPL5, RPL11, RPL15, RPL17, RPL19, RPL26, RPL27, RPL31, RPL35A) ribosomal subunit-associated protein in 80%-85% of the affected cases of DBA. In the remaining 10-15% of DBA cases, no abnormal genes have yet been identified. It is likely that mutations are in a regulatory region including intronic regions and promoters in one of the known RP genes and may account for the DBA phenotype.

Differentiating Diamond Black-fan Anemia from Other Diseases

Diamond Black-fan Anemia must be differentiated from other diseases that cause anemia and bone marrow failure such as Aplastic anemia, Fanconi anemia, Transient Erythroblastopenia of Childhood, Shwachman-Diamond syndrome, Pearson syndrome, Dyskeratosis congenita, Cartilage-hair hypoplasia, Congenital amegakaryocytic thrombocytopenia, Infections: Parvovirus B19, HIV, Viral hepatitis, Drugs, and toxins (eg. antileptic drugs, azathioprine), Immune-mediated disorders( eg Thymoma, Myasthenia Gravis, SLE).

Epidemiology and Demographics

The Incidence of Classical Diamond-Blackfan anemia (DBA) is about seven per million live births per year. Thus in the United States, with 4 million live births per year, each year, approximately 25-35 new patients will be diagnosed. The prevalence of DBA is approximately 5000 cases worldwide. DBA is usually first diagnosed in infancy. The average age of presenting with anemia is two months, and the average age of diagnosis with DBA is 3-4 months. There is no racial predilection to DBA. DBA affects men and women equally.

Risk Factors

Common risk factors in the development of DBA include positive family history, having a known genetic cause.

Screening

There is no routine screening.

Natural History, Complications, and Prognosis

DBA typically present with common symptoms of anemia, including pale skin, sleepiness, irritability, tachycardia. Common complications of DBA include physical abnormalities, Cancer predisposition, eye problems such as cataracts, glaucoma, or strabismus, kidney abnormalities, hypospadias, and secondary complications due to standard therapies( Corticosteroids treatment, Red cell transfusion, Bone marrow transplantation). Prognosis is relatively good, Overall actuarial survival is 75% at age 40 years

Diagnosis

  • Diagnosing DBA is usually hard due to its partial phenotypes and the wide inconsistency of clinical expressions. The International Clinical Consensus Conference stated diagnostic and supporting criteria for the diagnosis of DBA. Based on these criteria, There are two types of Diamond-Blackfan anemia, classical DBA and non-classical DBA. Classical DBA is made in the presence of all the diagnostic criteria and diagnosis of "non-classical DBA" in the presence of one of these criteria: i) Three diagnostic criteria and one major supporting criterion or two minor criteria; ii) Two diagnostic criteria, and three minor supporting criteria; iii) Two major supporting criteria, even in the absence of diagnostic criteria.
  • Diagnostic criteria
  • Major supporting criteria
    • Gene mutation described in ‘‘classical’’ DBA
    • Positive family history
  • Minor supporting criteria
    • Elevated erythrocyte adenosine deaminase activity
    • Congenital anomalies described in ‘‘classical’’ DBA
    • Elevated HbF
    • No evidence of another inherited bone marrow failure syndrome


Classical DBA

All diagnostic criteria are met.


Probable DBA

3 Diagnostic criteria + positive family history

OR

2 Diagnostic criteria + 3 minor criteria

OR

3 Minor criteria + positive family history


Non-classical DBA

DBA associated gene mutation without sufficient diagnostic criteria

History and Symptoms

Classic DBA: Symptoms of anemia include fatigue, weakness, and an abnormally pale appearance (pallor). The symptomatic onset of Diamond black-fan anemia becomes apparent during the first year of life. Approximately half of DBA cases have Congenital malformations, in particular craniofacial, upper-limb, heart, and genitourinary malformations. Non-classic DBA: presents with mild or absent anemia with only subtle indications of erythroid abnormalities such as macrocytosis, elevated ADA, and/or elevated HbF concentration. Have mild anemia beginning later in childhood or adulthood. In contrast, others have some physical features but no bone marrow problem, minimal or no evidence of congenital anomalies, or short stature.

Physical Examination

Common physical examination findings of DBA include signs of anemia such as pallor, tachycardia, and congenital abnormalities, particularly craniofacial, upper-limb, heart, and genitourinary malformations.

Laboratory Findings

A diagnosis of DBA is made on the basis of anemia, low reticulocyte (immature red blood cells) counts, and diminished erythroid precursors in the bone marrow. Blood tests, genetic tests, and bone marrow aspiration could help in the diagnosis of DBA.

Electrocardiogram

There are no chest x-ray findings associated with DBA. It can use for the diagnosis of congenital heart abnormalities or complications of iron overloads in transfusion red cell-dependent patients such as arrhythmia.

X-ray

There are no chest x-ray findings associated with DBA. It can use for the diagnosis of congenital physical abnormalities.

Echocardiography and Ultrasound

Renal ultrasound and echocardiography should be done to diagnosis any renal or cardiac abnormalities.

CT scan

There are no CT scan findings associated with DBA. It can use for the diagnosis of congenital physical abnormalities.

MRI

There are no MRI findings associated with DBA. It can use for the diagnosis of congenital physical abnormalities.

Other Imaging Findings

There are no other imaging findings associated with DBA.

Other Diagnostic Studies

Additional blood tests or genetic tests such as exome sequencing, genome sequencing, and mitochondrial sequencing may be ordered to rule out other types of anemia or other disorders.

Treatment

Medical Therapy

Treatment options:

  • Corticosteroids therapy
  • Red blood cell transfusion
  • Stem cell transplantations
  • Chelation therapy in iron overload
  • Cancer treatment

Interventions

  • Hematopoietic stem cell transplant (HSCT) is the sole curative option, but carries significant morbidity and is generally restricted to those with a matched related donor.
  • Ultimately, 40% of case subjects remain dependent upon corticosteroids which increase the risk of heart disease, osteoporosis, and severe infections.
  • Another 40% become dependent upon red cell transfusions which require regular chelation to prevent iron overload and increases the risk of alloimmunization and transfusion reactions, and can cause severe co-morbidities.

Surgery

Corrective surgery can be performed for the correction of congenital abnormalities.

Primary Prevention

Prevention of DBA mostly depends on early diagnosis, treatment, and management of congenital abnormalities and related-therapies complications and genetic counseling for patient's relatives.

Secondary Prevention

Following Initial Diagnosis, patients should be evaluated by:

  • a hematologist
  • a clinical geneticist for congenital malformations and to obtain a detailed family history
  • an ophthalmologist for glaucoma and cataract for individuals on steroid therapy
  • an Orthopedic evaluation for individuals with clinical findings suggestive of Klippel-Feil anomaly or Sprengel deformity
  • Orthopedic for individuals with upper-limb and/or thumb anomalies
  • Ultrasound examination of the kidney and urinary tract
  • a nephrologist and a urologist, as appropriate
  • a cardiologist including echocardiography
  • Developmental assessment

Prevention of secondary complications

  • Iron chelation
    • usually started after ten to 12 transfusions (170-200 mL/kg of packed red blood cells), when serum ferritin concentration reaches 1,000-1,500 µg/L, or when the hepatic iron concentration reaches 6-7 mg/g of dry weight liver tissue
      • Deferasirox is recommended in individuals age two years or older.
      • Desferrioxamine
  • Corticosteroids side effects:
    • One of the critical side effects of corticosteroids is growth retardation. If growth is severely impaired, corticosteroids should be stopped.[1]

Evaluation of Relatives at Risk with molecular genetic testing

References

  1. Adam MP, Ardinger HH, Pagon RA, Wallace SE, Bean L, Stephens K, Amemiya A, Clinton C, Gazda HT. PMID 20301769. Vancouver style error: initials (help); Missing or empty |title= (help)


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