Nontransferrin-bound iron in the plasma of haemodialysis patients after intravenous iron saccharate infusion.

BACKGROUND: Many haemodialysis patients treated with recombinant human erythropoietin (r-HuEPO) receive intravenous iron supplementation on a regular basis. It has been shown previously that this may result in a transient "oversaturation" of transferrin. METHODS: Ten stable haemodialysis patients on r-HuEPO treatment received 100 mg iron saccharate in 60 min, and 1 week later 100 mg in 6 min. Conventional iron metabolism parameters and nontransferrin-bond iron, detected with HPLC after addition of nitrilotriacetate and pretreatment with cobalt, were measured. Also, iron was measured in dialysate. RESULTS: Serum iron increased from 9.6 +/- 6.2 to 213.7 +/- 49.4 micromol L(-1) (P < 0.001) when iron was given in 60 min, and from 11.1 +/- 4.7 to 219.3 +/- 43.7 micromol L(-1) (P < 0.001) when iron was given in 6 min. Transferrin saturation increased from 0.22 +/- 0.18 to 4.75 +/- 1.35 in protocol 1 and 0.26 +/- 0.16 to 4.91 +/- 1.38 in protocol 2. Nontransferrin-bound iron increased from 0.74 +/- 0.69 to 3.79 +/- 1.41 micromol L(-1) in protocol 1, and from 0.90 +/- 0.92 to 2.90 +/- 0.96 micromol L(-1) in protocol 2. No significant iron concentrations were found in dialysate before or during the iron saccharate infusion. CONCLUSION: Nontransferrin-bound iron exists in plasma of dialysis patients after infusion of iron saccharate. There was no difference when 100 mg iron was given in 60 min or in 6 min. Before iron infusion, appreciable concentrations of nontransferrin-bound iron could already be detected. The clinical significance is not clear, but the findings may be important since nontransferrin-bound iron can act as a catalytic agent in the formation of hydroxyl radicals, thus potentially inducing cell damage and atherosclerosis.

Biliary and urinary metabolic profiles of 1,2-diethyl-3-hydroxypyridin-4-one (CP94) in the rat.

This study compares the biliary and urinary metabolic profiles of 1,2-diethyl-3-hydroxypyridin-4-one (CP94), an orally active iron chelator, in the normal rat. Surprisingly, CP94 was found to form two phase II metabolites, the 3-O- and 4-O-glucuronides. These glucuronides accounted for 38 and 28% of the administered CP94 dose, in bile and urine, respectively. Unchanged CP94 accounted for 5% of the CP94 dose in both bile and urine. The 2-(1'-hydroxy) metabolite of CP94 was found to be the dominant metabolite in urine. In addition, an unstable metabolite was detected in the bile although its structure remains unknown at the present stage. The excretion of iron in bile, after administration of CP94, was found to parallel the biliary elimination of CP94 together with its hydroxylated derivatives, indicating the importance of metabolites in iron excretion.

Determination of non-transferrin-bound iron in genetic hemochromatosis using a new HPLC-based method.

BACKGROUND/AIMS: Non-transferrin-bound iron may play a major pathogenic role in iron overload diseases due to its high hepatic uptake and potential damaging effect. The aim of this study was to evaluate the relevance of measuring serum non-transferrin-bound iron levels in genetic hemochromatosis using a new high performance liquid chromatography-based method. METHODS: This method includes a presaturation step of transferrin with cobalt(II) in order to avoid secondary deplacement of non-transferrin-bound iron toward transferrin during the assay. Six genetic hemochromatotic patients were followed serially during venesection treatment. RESULTS/CONCLUSIONS: The results indicate: (i) that this new method permits detection of non-transferrin-bound iron when transferrin is not fully saturated, (ii) that non-transferrin-bound iron levels persist almost until the completion of treatment, (iii) that non-transferrin-bound iron levels are well correlated with transferrin saturation for a given patient, and (iv) that despite some individual variations, a transferrin saturation value lower than 35% usually corresponds to the disappearance of non-transferrin-bound iron.

Non-transferrin-bound iron is present in serum of hereditary haemochromatosis heterozygotes.

BACKGROUND: Hereditary haemochromatosis (HH) is a common autosomal recessive disease. Recently, HH heterozygosity has been identified as an independent risk factor for myocardial infarction and cardiovascular mortality. Iron may play an important role in atherogenesis by catalyzing peroxidation of low-density-lipoprotein (LDL), an essential step in atherogenesis. In iron overload conditions, non-transferrin-bound iron (NTBI) is found in serum, which can catalyze lipid peroxidation. We investigated whether sera of HH heterozygotes contain more NTBI than sera of normal controls. METHODS: In 27 treated HH homozygotes, 22 HH heterozygotes and 17 healthy control subjects, conventional parameters of iron status (serum iron, transferrin saturation, serum ferritin) were measured. NTBI was detected using HPLC after addition of nitrilotriacetic acid and pretreatment with cobalt. RESULTS: The conventional parameters of iron status were similar in the HH heterozygous group and the control group. NTBI was significantly higher in homozygotes compared to heterozygotes (1.79 micromol L-1 vs. 0.51 micromol L-1, 95% CI of the difference = 0.6-1.95, P < 0.001), and controls (1.79 micromol L-1 vs. - 0.3 micromol L-1, 95% CI of the difference = 1.36-2.81, P < 0.001). The difference in NTBI between the heterozygous subjects and control subjects was also significant (0.51 micromol L-1 vs. - 0. 3 micromol L-1, 95% CI of the difference = 0.05-1.57, P < 0.05). CONCLUSION: Phlebotomy treated HH homozygotes maintain a high and potentially harmful serum NTBI. HH heterozygotes have a higher serum NTBI than normal controls. The reported increased risk of cardiovascular events in heterozygous haemochromatosis may be explained by NTBI-catalyzed LDL peroxidation.

Quantification of non-transferrin-bound iron in the presence of unsaturated transferrin.

Non-transferrin-bound iron (NTBI) has been reported to be associated with several clinical states such as thalassemia, hemochromatosis, and in patients receiving chemotherapy. We have investigated a number of ligands as potential alternatives to nitrilotriacetic acid (NTA) to capture NTBI without chelating transferrin- or ferritin-bound iron in plasma. We have established, however, that NTA is the optimal ligand to chelate the different forms of NTBI present in sera and can be adopted for utilization in the NTBI assay. NTA (80 mM) removes all forms of NTBI, while only mobilizing a small fraction of the iron bound to both transferrin and ferritin. We have compared three different detection systems for the quantification of NTA-chelated NTBI: the established HPLC-based method, a simple colorimetric method, and a method based on inductive conductiometric plasma spectroscopy. The sensitivity and reproductibility of the colorimetric method were acceptable compared with the other two methods and would be more convenient as a routine laboratory screening assay for NTBI. However, the limitations of this method are such that it can only be utilized in situations where desferrioxamine is not used and when transferrin saturation levels are close to 100%. Only the HPLC-based method is applicable for patients receiving (desferrioxamine) chelation therapy. In some diseases such as hemochromatosis, transferrin may be incompletely saturated. In such cases, to avoid in vitro donation of iron onto the vacant sites of transferrin, sodium-tris-carbonatocobaltate(III) can be added to block the free iron binding sites on transferrin. If this step is not taken, there may be an underestimation of NTBI values.