Thalassemia laboratory findings

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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor(s)-in-Chief: Shyam Patel [2] Neel Patel, M.B.B.S[3]

Overview

Laboratory findings in patients with thalassemia include anemia with microcytosis, abnormal bands on hemoglobin electrophoresis, and abnormal peripheral blood smear findings. Sequencing of the globin genes will reveal mutations that lead to defective globin production. In the case of hemolysis from thalassemia, laboratory findings include elevated LDH, elevated total bilirubin, elevated indirect bilirubin, high reticulocyte count, and low haptoglobin. Importantly, the range of laboratory findings is quite diverse depending on the severity of the disease.

Laboratory Findings

Mean corpuscular volume

The accuracy of the mean corpuscular volume (MCV) < 80 fl for diagnosing thalassemia traits (defined as hemoglobin A2 4.1–9.0%) is:[2]

Red blood cell count

A red blood cell count > 5 suggests thalassemia[3].

Mentzer index

The Mentzer index suggest thalassemia if less than 13 and suggests iron deficiency anemia if over 13.[4][5]

<math>\text{Mentzer index} = \frac{mean\ corpuscular\ volume}{RBC\ count}</math>

Green & King Index

Green & King Index is:[3]

<math>\text{Green and King Index} = MCV^2 + \frac{RDW}{Hb * 100}</math>

A Green and King Index < 73 suggests thalassemia and was more sensitive than other tests in a comparison[3].

MCV [2] × RDW / (Hb×100)

Hemoglobin A2

The accuracy of an elevated hemoglobin A2 at detecting abnormal DNA testing is uncertain. There are several situations in which its value will be normal:[6]

  • Specific mild mutations such as the Beta+ IVS-1 nt6 mutation
  • In delta beta-thalassemia, creation of Hemoglobin A2 is impaired due to delta.[7]
  • The triple alpha globin arrangement.[8]
  • Silent beta thalassemia, which also has mean corpuscular volume. The most common mutation for this is the -101 C to T substitution with the distal CACC box.[9]


Other tests

  • Elevated red blood cell mass: This is a somewhat unique feature of thalassemia. A low hemoglobin plus elevated red blood cell mass should prompt a clinician to consider thalassemia as the cause of anemia. In contrast, patients with iron deficiency anemia have low hemoglobin but do not have elevated red blood cell mass.
  • Hypochromasia: Red blood cells in thalassemia have central pallor, similar to red blood cells in iron-deficiency anemia.[1]
  • Elevated lactate dehydrogenase (LDH): This is due to hemolysis, in which intracellular contents (such as LDH) are released into the circulation.
  • Indirect, or unconjugated, hyperbilirubinemia: This is due to hemolysis, in which breaskdown products of heme are released into the bloodstream.
  • Low haptoglobin: This is due to hemolysis, in which free hemoglobin in the circulation binds to and reduces the level of haptoglobin.
  • Elevated reticulocyte count: This is due to a bone marrow compensatory response to low hemoglobin levels from thalassemia. Reticulocytes are precursors of red blood cells and thus an elevated reticulocyte count signifies an adequate compensatory attempt to produce more red blood cells.
  • Abnormal bands on hemoglobin electrophoresis: Hemoglobin electrophoresis is the gold standard diagnostic test for thalassemia. In normal persons, a hemoglobin electrophoresis will show a strong band corresponding to hemoglobin A (tetramer of 2 alpha-globin chains and 2 beta-globin chains) and a weak band corresponding to hemoglobin A2 (tetramer of 2 alpha-globin chains and 2 delta-globin chains). In thalassemia, various other bands can be present on electrophoresis. These include tetramers of gamma-globin chains (such as in Hb Barts) or tetramers of beta-globin chains (such as in HbH disease).
  • Abnormal cells on peripheral blood smear: The peripheral blood smear is perhaps the most inexpensive laboratory test that can accurately lead to a diagnosis of thalassemia. Patients with thalassemia have target cells and hypochromic (low color) and microcytic (small-sized) red blood cells.
  • Mutations in alpha-globin on DNA sequencing: This is a specialized test that can definitively determine the presence of alpha-thalassemia. Sequencing of the alpha-globin chain from peripheral blood cells can help diagnose alpha-thalassemia. This laboratory test is more expensive than the other tests. These laboratory findings are pathognomonic for alpha-thalassemia. Deletions or insertions are more common in the alpha-globin gene compared to the beta-globin gene.
  • Mutations in beta-globin on DNA sequencing: This is a specialized test that can definitively determine the presence of beta-thalassemia. Sequencing of the beta-globin chain from peripheral blood cells can help diagnose beta-thalassemia. This laboratory test is more expensive than the other tests. These laboratory findings are pathognomonic for beta-thalassemia. Point mutations (substitutions) are more common in the beta-globin gene compared to the alpha-globin gene.

Peripheral Smear

(Images shown below are courtesy of Melih Aktan MD, Istanbul Medical Faculty - Turkey, and Kyoto University - Japan, and Hospital Universitario La Fe Servicio Hematologia)


References

  1. 1.0 1.1 Chui DH, Cunningham MJ, Luo HY, Wolfe LC, Neufeld EJ, Steinberg MH (2006). "Screening and counseling for thalassemia". Blood. 107 (4): 1735–7. doi:10.1182/blood-2005-09-3557. PMC 1895412. PMID 16461765.
  2. Sirichotiyakul S, Maneerat J, Sa-nguansermsri T, Dhananjayanonda P, Tongsong T (2005). "Sensitivity and specificity of mean corpuscular volume testing for screening for alpha-thalassemia-1 and beta-thalassemia traits". The journal of obstetrics and gynaecology research. 31 (3): 198–201. doi:10.1111/j.1447-0756.2005.00280.x. PMID 15916654. Unknown parameter |month= ignored (help)
  3. 3.0 3.1 3.2 Green R, King R (1989). "A new red cell discriminant incorporating volume dispersion for differentiating iron deficiency anemia from thalassemia minor". Blood Cells. 15 (3): 481–91, discussion 492-5. PMID 2620095.
  4. Mentzer WC (1973). "Differentiation of iron deficiency from thalassaemia trait". Lancet. 1 (7808): 882. doi:10.1016/s0140-6736(73)91446-3. PMID 4123424.
  5. Ntaios G, Chatzinikolaou A, Saouli Z, Girtovitis F, Tsapanidou M, Kaiafa G; et al. (2007). "Discrimination indices as screening tests for beta-thalassemic trait". Ann Hematol. 86 (7): 487–91. doi:10.1007/s00277-007-0302-x. PMID 17476506.
  6. Cao A, Saba L, Galanello R, Rosatelli MC (1997). "Molecular diagnosis and carrier screening for beta thalassemia". JAMA. 278 (15): 1273–7. PMID 9333270. Unknown parameter |month= ignored (help)
  7. "HEMOGLOBIN--DELTA LOCUS; HBD". Online Mendelian Inheritance in Man. Retrieved 2008-11-10.
  8. "HEMOGLOBIN--ALPHA LOCUS 1; HBA1". Online Mendelian Inheritance in Man. Retrieved 2008-11-10.
  9. "THALASSEMIA, BETA+, SILENT ALLELE". Online Mendelian Inheritance in Man. Retrieved 2008-11-10.

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