Tag Archives: Serum Ferritin

Iron Studies in Microcytic Anaemia


Diagnosis Serum Iron Total Iron Binding Capacity Transferrin1 Serum Ferritin2
Iron deficiency anaemis Low High or Normal <16% <12ng/mL
Anaemia of Chronic Disease Normal Low or Normal ≥16% High or normal
β-Thalasaemia Trait, HbE, HbC Normal Normal ≥16% Normal
Sideroblastic Anaemia High Normal High High
  1. Two causes of microcytic anaemia may co-exist e.g. thalassaemia trait with iron deficiency anaemia or anaemia of chronic disease with iron deficiency anaemia. When iron deficiency exists with other forms of microcytic anaemia the transferrin saturation is <16%
  2. Patients with low ferritin (<12ng/ml) always have iron deficiency. Higher values of ferritin do not exclude iron deficiency particularly in patients with anaemia of chronic disease. There are no guidelines about the ferritin levels that exclude iron deficiency in patients of anaemia of chronic disease. The reported values vary between 60-100ng/ml.

Laboratory diagnosis of Iron Deficiency


The investigation to diagnose iron deficiency include:

  1. Haemoglobin and red cell parameters
  2. Bone marrow iron staining
  3. Serum Iron, total iron binding capacity and transferrin saturation
  4. Serum ferritin
  5. Zinc Protoporphyrin
  6. Soluble transferrin receptor

Haemoglobin and Red cell Parameters

Patients undergo evaluation for iron deficiency because they are anaemic. Latent iron deficiency is characterized by a progressive decrease in bone marrow iron stores in patients who have yet not developed symptoms. These patients are asymptomatic and latent iron deficiency is not a clinical problem. Iron deficiency causes microcytic hypochromic anaemia. There are no reliable test to differentiate iron deficiency from other causes of microcytic hypochromic anaermia.  The red cell indices that have been proposed to be useful include

  1. Red cell distribution width (RDW): RDW is a measure of anisocytosis. Iron deficiency anaemia shows more anisocytosis than β-thalassaemia and is associated with a higher RDW. The promise held out by RDW to differentiate iron deficiency and thalassaemia has not fulfilled.
  2. Reticulocyte haemoglobn content: Changes in erythropoiesis are reflected earliest in the reticulocyte. Reticulocytes form a small fraction of erythrocytes. Change in reticulocyte indices do not change erythrocyte indices. Some automated counters are able to measure reticulocyte indices. Reticulocyte haemoglobin content falls with iron deficiency anaemia but the finding is not specific. It has been found to asses iron deficiency in patient of chronic renal failure being treated with erythropoietin accurately. It has not been found to be useful in diagnosing iron deficiency in patients with thalassaemia.

Bone Marrow Iron Staining

Bone marrow is stained for iron content by the Prussian blue reaction and graded in a semiquantative method. Bone marrow iron is the gold standard for diagnosis of iron deficiency. The test is invasive and suffers from an inter-observer variation. Bone marrow iron staining is resorted to only when diagnosis can not be reached by other methods.

Serum iron, total iron binding capacity and transferrin saturation

Iron deficiency is diagnosed by a transferrin saturation of less than 16%. The serum iron is low and the total iron binding capacity is usually increased. Patients with low total iron binding capacity have anaemia of chronic disease if the transferrin saturation is ≥16%  or iron deficiency along with anaemia of chronic disease if the transferrin saturation is <16%.

Serum ferritin

Ferritin is one of the iron storage proteins. Serum ferritin levels co-relates with body iron content. A ferritin level less than 12ng/mL is diagnostic of iron deficiency. Inflammation increases ferritin. Chronic inflammatory diseases like rheumatoid arthritis and ulcerative colitis have anaemia of chronic disease and may also have iron deficiency. A patient with iron deficiency in the setting of an inflammatory disease may not have a low ferritin. There is no consensus for diagnosing iron deficiency in patients with anaemia of chronic disease. Inflammation rarely increases the serum ferritin values more than 60-100ng/mL. Iron deficiency can be excluded in patients with ferritin above this cutoff.

Zinc Portoporphyrin

Iron is added to propoporphyrin in the final step of heme synthesis. Zinc takes the place of iron in patients with iron deficiency. A rise in the concentration of zinc protoporphyrin is the earliest manifestations of iron deficiency. Zinc protoporphyrin levels rise in about 2 weeks from the onset of iron deficiency and need more than a month to normalize after restoration of normal iron levels.

Soluble transferrin Receptor

Iron deficiency results in an increase in soluble transferrin receptor (sTfR). Inflammation impacts serum ferritin but not sTfR making it a potentially useful investigation for differentiating anaemia of chronic disease and iron deficiency. The assay has been difficult to standardize. A ratio of sTfR/log ferritin is more useful.

The sTfR levels reflect the density of transferrin receptors cells and number of cells. sTfR increases when there is erythroid hyperplasia due to any cause like haemolytic anaemia and may not reflect iron deficiency in these disorders.