Investigation and management of a raised serum ferritin.

Serum ferritin level is one of the most commonly requested investigations in both primary and secondary care. Whilst low serum ferritin levels invariably indicate reduced iron stores, raised serum ferritin levels can be due to multiple different aetiologies, including iron overload, inflammation, liver or renal disease, malignancy, and the recently described metabolic syndrome. A key test in the further investigation of an unexpected raised serum ferritin is the serum transferrin saturation. This guideline reviews the investigation and management of a raised serum ferritin level. The investigation and management of genetic haemochromatosis is not dealt with however and is the subject of a separate guideline.

Improved detection of hereditary haemochromatosis.

AIMS: There is high prevalence of hereditary haemochromatosis (HH) in North European populations, yet the diagnosis is often delayed or missed in primary care. Primary care physicians frequently request serum ferritin (SF) estimation but appear uncertain as how to investigate patients with raised SF values. Our aim was to develop a laboratory algorithm with high predictive value for the diagnosis of HH in patients from primary care with raised SF values. METHODS: Transferrin saturation (Tsat) was measured on SF samples sent from primary care; 1657 male and 2077 female patients age ≥ 30 years with SF ≥ 200 µg/L. HFE genotyping was performed on all 878 male and 867 female patients with Tsat >30%. RESULTS: This study identified 402 (206 men; 196 women) C282Y carriers and 132 (58 men; 74 women) C282Y homozygotes. Optimal limits for combined SF and Tsat values for HH recognition were established. The detection rate for homozygous C282Y HH for male patients with both SF ≥ 300 µg/L and Tsat >50% was 18.8% (52/272) and 16.3% (68/415) for female patients with both SF ≥ 200 µg/L and Tsat >40%. CONCLUSIONS: The large number of SF requests received from primary care should be used as a resource to improve the diagnosis of HH in areas of high prevalence.

Serum ferritin values in primary care: are high values overlooked?

OBJECTIVE: To examine serum ferritin values in iron-replete patients in primary care and determine the action taken on those patients with very high values (>1000 µg/l). METHODS: Serum ferritin values from 4170 consecutive patients in primary care were examined. All measurements had been made at the request of the general practitioner. RESULTS: Ferritin values in males reached a steady state by 30 years and did not increase thereafter. Values above 300 µg/l were found in 17% of all males. Female values rose progressively with age. Less than 10% of women <50 years had values >100 µg/l. By the age of 70 years, 8% had values >300 µg/l. Ferritin values >1000 µg/l were found in 59 patients. This rise was neither explained nor investigated in 32 cases. CONCLUSION: Raised ferritin values are frequently found in samples submitted from primary care and most so in adult males. The authors also conclude that general practitioners require more guidance from haematologists in the management of patients with very high values.

Erythroblast iron metabolism in sideroblastic and sideropenic states.

Iron appears to exert self-regulatory control over erythroblast iron uptake, iron storage and its incorporation into haem. It does this via iron regulatory proteins (IRPs) which bind reversibly to the iron responsive elements (IREs) on the mRNA of transferrin receptor (TfR), erythroid 5-aminolaevulinic acid synthase (ALA-S2) and ferritin. Iron deficiency leads to the binding of IRP to IRE. This binding inhibits the translation of mRNA for ALA-S2 and ferritin but stabilizes mRNA for TfR expression. Sideroblastic erythropoiesis is highly ineffective and characterized by mitochondrial iron loading. The study of X-linked sideroblastic anaemia has shown that the entry of iron into the mitochondria is poorly controlled and able to occur when protoporphyrin production is reduced, as is seen with the ALA-S2 mutations, or when it is increased as has been seen with ABC7 transporter mutations. Sideropenia characterises both iron deficiency anaemia (IDA) and the anaemia of chronic disease (ACD). Erythroblasts in ACD seem doubly equipped to protect their iron supply with their ability to increase the efficiency of transferrin-iron uptake as well as to activate the IRP/IRE system to increase surface TfR production. This increase in efficiency restricts the need to increase surface TfR production and maintains serum soluble TfR (sTfR) values within the normal range in iron replete ACD. The coexistence of iron deficiency with chronic disease, however, is associated with an increase in both the efficiency and number and a highly significant rise in sTfR values.

Erythroblast iron metabolism and serum soluble transferrin receptor values in the anemia of rheumatoid arthritis.

OBJECTIVES: We have investigated in vitro erythroblast iron metabolism in the anemia of rheumatoid arthritis (RA). We also have examined the results in relation to bone marrow iron status in an attempt to explain the reported difference between serum soluble transferrin receptor (sTfR) values in anemia of chronic disease (ACD) and iron deficiency anemia (IDA) in patients with RA. METHODS: Bone marrow was examined in 29 anemic patients with RA, 9 healthy volunteers, and 6 patients with simple IDA. High purity erythroblast fractions were prepared from these bone marrow samples. Erythroblast surface TfR expression and iron uptake was assessed in vitro using (125)I-transferrin (Tf) and (59)Fe-Tf, respectively. The efficiency of erythroblast surface TfR function for Tf-iron uptake was determined by relating total iron uptake at 4 hours to surface TfR number. Serum sTfR values were measured for the RA anemia group, which was subdivided as RA-ACD (marrow iron present) or RA-IDA (marrow iron absent) on the basis of visible reticuloendothelial (RE) marrow iron stores. RESULTS: High purity (87 +/- 5%) erythroblast fractions were obtained from 35 of the 44 marrow samples. Erythroblasts obtained from patients with simple IDA showed a significant increase in surface TfR expression (P = 0.0003) and Tf-iron uptake (P = 0.001). RA anemia also led to a significant increase in erythroblast Tf-iron uptake (P = 0.016). This increase was not associated with an increase in surface TfR expression (P = 0.5), but was seen to occur as a result of a significant increase in the efficiency of surface TfR for Tf-iron uptake (P = 0.027). Within the RA anemia group, the increase in erythroblast Tf- iron uptake at 4 hours was more evident for RA-IDA (3.96 +/- 1.73 versus 1.66 +/- 0.66; P = 0.03) than for RA-ACD (2.69 +/- 1.18 versus 1.66 +/- 0.66; P = 0.057). This additional erythroblast response to absent RE iron stores led to a highly significant difference in serum sTfR values between RA-IDA and RA-ACD (40.2 +/- 14.0 versus 23.9 +/- 5.3 nmoles/liter; P = 0.001) CONCLUSIONS: An increase in erythroblast surface TfR efficiency for Tf-iron uptake compensates for the low plasma iron levels associated with anemia in RA and helps to maintain RA erythroblast iron uptake. With adequate RE iron stores, this increased efficiency limits intracellular iron deprivation and consequently reduces the need to increase surface TfR expression. As a result, serum sTfR levels in RA-ACD remain within the normal range. RA erythroblasts, however, are still able to respond to any additional worsening of the iron supply caused by absent RE iron stores. This additional response causes the highly significant increase in serum sTfR values seen between RA-IDA and RA-ACD.