[Conclusions and recommendations of a WHO expert consultation meeting on iron supplementation for infants and young children in malaria endemic areas]. / Conclusions et recommandations à l'issue de la consultation de l'OMS sur la lutte contre la carence martiale chez le nourrisson et le jeune enfant dans les pays d'endémie palustre.

This article presents the results of an expert consultation meeting aimed at evaluating the safety and public health implications of administering supplemental iron to infants and young children in malaria-endemic areas. Participants at this meeting that took place in Lyon, France on June 12-14, 2006 reached consensus on several important issues related to iron supplementation for infants and young children in malaria-endemic areas. The conclusions in this report apply specifically to regions where malaria is endemic.

[Lead poisoning by contaminated flour: an unfinished story].

A young Arab woman was diagnosed with severe lead poisoning in the early 80's. Detailed epidemiologic studies revealed many additional cases of lead poisoning in the rural population south of Nablus and a population survey conducted among schoolchildren revealed increased blood lead levels in 30% of the children. The source of poisoning was contamination from home-made flour by lead fillings used to secure the housing of the driveshaft to the millstone. Of the 146 village mills surveyed, lead concentrations in freshly ground flour exceeding 1.5 ppm were found in 8% of the mills. Following our original report, identical outbreaks caused by contaminated flour were reported from Spain, Turkey, Greece and Albania. In spite of administrative efforts to prevent the use of lead in flour mills, the problem still persists. In Israel itself, similar subsequent outbreaks have been documented in the Upper Galilee, and recently in the Hebron district. Apparently, the problem has existed since antiquity because flour mills employing lead parts were introduced to this and other countries during the Roman conquest. A coordinated international effort is essential to eliminate this unique and serious health threat from the environment.

Reversal of cardiac complications in thalassemia major by long-term intermittent daily intensive iron chelation.

OBJECTIVES: In patients with thalassemia major (TM) who are non-compliant with long-term deferoxamine (DFO) chelation, survival is limited mainly because of cardiac complications of transfusional siderosis. It was recently shown in a small group of TM patients with established cardiac damage that continuous 24-h DFO infusion via an indwelling intravenous (i.v.) catheter is effective in reversing cardiac toxicity. The aim of the present study was to evaluate the results with intermittent daily (8-10 h) i.v. DFO. PATIENTS: Eight TM patients with cardiac complications treated with intensive intermittent DFO were retrospectively evaluated by the mean annual serum ferritin, radionucleated ventriculography and 24-h electrocardiography recordings. RESULTS: The median age at diagnosis of cardiac disease was 17.5 yr (range 14-21), and the median follow-up time was 84 months (range, 36-120). In the majority of patients (seven of eight) high-dose DFO (mean 95 +/- 18.3 mg/kg/d) was administered via a central venous line. During follow-up, there was a significant decrease in the mean ferritin levels (5828 +/- 2016 ng/mL to 1585 +/- 1849 ng/mL, P < 0.001). Both cardiac failure (mean ejection fraction 32 +/- 5) and cardiac arrhythmias were resolved in four of five patients. One non-compliant patient died during the follow-up. Following discontinuation of the i.v. therapy, compliance with conventional DFO therapy improved. The complications of this regimen, mainly catheter-related infections and catheter-related thrombosis, were similar to those described earlier. CONCLUSIONS: These results with the longest follow-up period in the literature suggest that i.v. high-dose DFO for 8-10 h daily may be as effective as continuous 24-h infusion for the reversal of established cardiac disease in TM.

Objectives and methods of iron chelation therapy.

Recent developments in the understanding of the molecular control of iron homeostasis provided novel insights into the mechanisms responsible for normal iron balance. However in chronic anemias associated with iron overload, such mechanisms are no longer sufficient to offer protection from iron toxicity, and iron chelating therapy is the only method available for preventing early death caused mainly by myocardial and hepatic damage. Today, long-term deferoxamine (DFO) therapy is an integral part of the management of thalassemia and other transfusion-dependent anemias, with a major impact on well-being and survival. However, the high cost and rigorous requirements of DFO therapy, and the significant toxicity of deferiprone underline the need for the continued development of new and improved orally effective iron chelators. Within recent years more than one thousand candidate compounds have been screened in animal models. The most outstanding of these compounds include deferiprone (L1); pyridoxal isonicotinoyl hydrazone (PIH) and; bishydroxy- phenyl thiazole. Deferiprone has been used extensively as a substitute for DFO in clinical trials involving hundreds of patients. However, L1 treatment alone fails to achieve a negative iron balance in a substantial proportion of subjects. Deferiprone is less effective than DFO and its potential hepatotoxicity is an issue of current controversy. A new orally effective iron chelator should not necessarily be regarded as one displacing the presently accepted and highly effective parenteral drug DFO. Rather, it could be employed to extend the scope of iron chelating strategies in a manner analogous with the combined use of medications in the management of other conditions such as hypertension or diabetes. Coadministration or alternating use of DFO and a suitable oral chelator may allow a decrease in dosage of both drugs and improve compliance by decreasing the demand on tedious parenteral drug administration. Combined use of DFO and L1 has already been shown to result in successful depletion of iron stores in patients previously failing to respond to single drug therapy, and to lead to improved compliance with treatment. It may also result in a "shuttle effect" between weak intracellular chelators and powerful extracellular chelators or exploit the entero-hepatic cycle to promote fecal iron excretion. All of these innovative ways of chelator usage are now awaiting evaluation in experimental models and in the clinical setting.

The iron-loaded gerbil model revisited: effects of deferoxamine and deferiprone treatment.

Although the beneficial effects of deferoxamine (DFO) on iron-associated morbidity and mortality are well documented, the role of deferiprone (L1) in the management of transfusional iron overload is controversial. This debate involves not only the question of efficacy but also of safety, with particular emphasis on the risk of a paradoxical aggravation of iron toxicity by L1. We used the iron-loaded gerbil model introduced by Carthew et al to compare the chelating efficacy of L1, DFO, or both in two gerbil strains treated by means of weekly iron-dextran injections: Psammomys obesus and pathogen-free Mongolian gerbils (Meriones unguiculatus). The difference between the high mortality and advanced hepatocellular necrosis observed in iron-loaded P obesus and the absence of mortality and limited morbidity encountered in pathogen-free Mongolian gerbils is most likely explained by the prevention of coincidental laboratory infections in the latter group. Iron-chelating treatment in all experimental groups resulted in a significant decrease in hepatic iron concentrations and normalization of mitochondrial respiratory enzyme activities, with combined L1 and DFO treatment being the most efficient, followed, in decreasing order, by DFO and L1 as single-drug treatments. Judged by tissue iron concentrations, mitochondrial enzyme activity, and hepatic histology, we could find no evidence of a paradoxical aggravation of iron toxicity by L1 in either of the two series of studies. Although these data appear to be reassuring, the present controversy related to the role of L1 in the development of hepatic cirrhosis should be eventually settled by clinical studies evaluating the effects of long-term iron-chelating treatment.

Exploring the "iron shuttle" hypothesis in chelation therapy: effects of combined deferoxamine and deferiprone treatment in hypertransfused rats with labeled iron stores and in iron-loaded rat heart cells in culture.

Although iron chelation therapy results in a significant improvement in well-being and life expectancy of thalassemic patients with transfusional iron overload, failure to achieve these goals in a substantial proportion of patients underlines the need for improved methods of treatment. In the present studies we used selective radioactive iron probes of hepatocellular and reticuloendothelial (RE) iron stores in hypertransfused rats and iron-loaded heart cells to compare the source of iron chelated in vivo by deferoxamine (DFO) or by deferiprone (L1) and its mode of excretion, to examine the ability of DFO and L1 to remove iron directly from iron-loaded myocardial cells, and to examine the mechanism of their combined interaction through a possible additive or synergistic effect. Our results indicate that L1 given orally is 1.6 to 1.9 times more effective in rats, on a weight-per-weight basis, than parenteral DFO in promoting the excretion of storage iron from parenchymal iron stores but shows no advantage over DFO in promoting RE iron excretion. Simultaneous administration of DFO and L1 results in an increase in chelating effect that is additive but not synergistic. The magnitude of this additive effect is identical to an increase in the equivalent (weight or molar) dose of DFO alone rather than the sum of the separate effects of L1 and DFO. This finding is most probably the result of a transfer of chelated iron from L1 to DFO. These observations may have practical implications for current efforts to design better therapeutic strategies for the management of transfusional iron overload.

Increased warfarin sensitivity as an early manifestation of occult prostate cancer with chronic disseminated intravascular coagulation.

Increased sensitivity to warfarin anticoagulation is usually attributed to liver disease, vitamin K deficiency, or drug interactions. We describe a patient with unexplained sensitivity to warfarin and mildly elevated prostate-specific antigen levels in whom subsequent developments indicated that warfarin sensitivity was the first manifestation of occult prostatic cancer. A review of all published cases of coagulopathy associated with cancer of the prostate shows that, unlike other solid tumors with secondary disseminated intravascular coagulation (DIC), in prostate cancer increased bleeding is more common than thrombotic phenomena. Chronic DIC due to occult prostate cancer should be included in the differential diagnosis of excessive prothrombin time prolongation in patients receiving anticoagulants.

Desferrioxamine-chelatable iron, a component of serum non-transferrin-bound iron, used for assessing chelation therapy.

This study introduces a method for monitoring a component of serum non-transferrin-bound iron (NTBI), termed "desferrioxamine-chelatable iron" (DCI). It is measured with the probe fluorescein-desferrioxamine (Fl-DFO), whose fluorescence is stoichiometrically quenched by iron. DCI was found in the serum of most patients with thalassemia major (21 of 27 tested, range 1.5-8.6 microM), but only in a minority of patients with hereditary hemochromatosis (8 of 95 samples from 39 patients, range 0.4-1.1 microM) and in none of 48 controls. The method was applied to monitoring the appearance of iron in the serum of patients under chelation therapy. Short-term (2 hours) follow-up of patients immediately after oral administration of deferriprone (L1) showed substantial mobilization of DCI into the serum (up to 10 microM within 30-60 minutes). The transfer of DCI from L1 to Fl-DFO was observed in vitro with preformed L1-iron complexes, and occurred even at L1/iron ratios exceeding 3:1. Simultaneous administration of oral L1 and intravenous DFO to patients abrogated the L1-mediated rise in DCI, consistent with the shuttling of iron from L1 to DFO in vivo. A similar iron transfer from L1 to apo-transferrin was observed in vitro, lending experimental support to the notion that L1 can shuttle iron in vivo to other high-affinity ligands. These results provide a rationale for using chelator combinations, with the highly permeant L1 acting as an intracellular chelator-shuttle and the less permeant DFO serving as an extracellular iron sink. Potential applications of the DCI assay may be for studying chelator action and as an index of patient chelation status.

ICL670A: a new synthetic oral chelator: evaluation in hypertransfused rats with selective radioiron probes of hepatocellular and reticuloendothelial iron stores and in iron-loaded rat heart cells in culture.

ICL670A (formerly CGP 72 670) or 4-[3,5-bis-(hydroxyphenyl)-1,2,4-triazol-1-yl]- benzoic acid is a tridentate iron-selective synthetic chelator of the bis-hydroxyphenyl-triazole class of compounds. The present studies used selective radioiron probes of hepatocellular and reticuloendothelial (RE) iron stores in hypertransfused rats and iron-loaded heart cells to define the source of iron chelated in vivo by ICL670A and its mode of excretion, to examine its ability to remove iron directly from iron-loaded myocardial cells, and to examine its ability to interact with other chelators through a possible additive or synergistic effect. Results indicate that ICL670A given orally is 4 to 5 times more effective than parenteral deferoxamine (DFO) in promoting the excretion of chelatable iron from hepatocellular iron stores. The pattern of iron excretion produced by ICL670A is quite different from that of DFO and all iron excretion is restricted to the bile regardless of whether it is derived from RE or hepatocellular iron stores. Studies in heart cell cultures have shown a favorable interaction between DFO and ICL670A manifested in improved chelating efficiency of ICL670A, which is most probably explained by an exchange of chelated iron between ICL670A and DFO. These unique chelating properties of ICL670A may have practical implications for current efforts to design better therapeutic strategies for the management of transfusional iron overload.

The importance of non-transferrin bound iron in disorders of iron metabolism.

The concept of non-transferrin bound iron (NTBI) was introduced 22 years ago by Hershko et al. (Brit. J. Haematol. 40 (1978) 255). It stemmed from a suspicion that, in iron overloaded patients, the large amounts of excess iron released into the circulation are likely to exceed the serum transferrin (Tf) iron-binding capacity (TIBC), leading to the appearance of various forms of iron not bound to Tf. In accordance with this assumption, NTBI was initially looked for and detected in patients with > or = 100% Tf-saturation. As techniques for its detection became more sophisticated and sensitive, NTBI was also found in conditions where Tf was not fully saturated, leading to a revision of the original view of NTBI as a simple spillover phenomenon. In this review, we will discuss some of the properties of NTBI, methods for its detection, its significance and potential value as an indicator for therapeutic regimens of iron chelation and supplementation.

Re-emergence of lead poisoning from contaminated flour in a West Bank Palestinian village.

Although contaminated flour was first described as an important source of endemic lead poisoning in the Middle East almost 20 years ago, the use of lead in community flour mills has not been eliminated and continues to represent a significant environmental risk. The authors describe an outbreak of lead poisoning in a West Bank Palestinian family and draw attention to this unusual but important source of lead exposure. All 13 members of the family (two children and 11 adults), were found to have lead poisoning following hospitalization for "gastroenteritis," headache, joint pain, weight loss, and vision difficulties. Seven females had low hemoglobin levels. Blood lead concentrations ranged from 42 to 84 microg/dL. Household flour samples obtained from a stone mill, previously closed because of lead contamination, contained 2,000 ppm lead. Flour from traditional stone mills reinforced with lead joints remains a potential source for lead poisoning.

The assessment of serum nontransferrin-bound iron in chelation therapy and iron supplementation.

Nontransferrin-bound iron (NTBI) appears in the serum of individuals with iron overload and in a variety of other pathologic conditions. Because NTBI constitutes a labile form of iron, it might underlie some of the biologic damage associated with iron overload. We have developed a simple method for NTBI determination, which operates in a 96-well enzyme-linked immunosorbent assay format with sensitivity comparable to that of previous assays. A weak ligand, oxalic acid, mobilizes the NTBI and mediates its transfer to the iron chelator deferoxamine (DFO) immobilized on the plate. The amount of DFO-bound iron, originating from NTBI, is quantitatively revealed in a fluorescence plate reader by the fluorescent metallosensor calcein. No NTBI is found in normal sera because transferrin-bound iron is not detected in the assay. Thalassemic sera contained NTBI in 80% of the cases (range, 0.9-12.8 micromol/L). In patients given intravenous infusions of DFO, NTBI initially became undetectable due to the presence of DFO in the sera, but reappeared in 55% of the cases within an hour of cessation of the DFO infusion. This apparent rebound was attributable to the loss of DFO from the circulation and the possibility that a major portion of NTBI was not mobilized by DFO. NTBI was also found in patients with end-stage renal disease who were treated for anemia with intravenous iron supplements and in patients with hereditary hemochromatosis, at respective frequencies of 22% and 69%. The availability of a simple assay for monitoring NTBI could provide a useful index of iron status during chelation and supplementation treatments. (Blood. 2000;95:2975-2982)

Regulation of intracellular iron metabolism in human erythroid precursors by internalized extracellular ferritin.

Human erythroid precursors grown in culture possess membrane receptors that bind and internalize acid isoferritin. These receptors are regulated by the iron status of the cell, implying that ferritin iron uptake may represent a normal physiologic pathway. The present studies describe the fate of internalized ferritin, the mechanisms involved in the release of its iron, and the recognition of this iron by the cell. Normal human erythroid precursors were grown in a 2-phase liquid culture that supports the proliferation, differentiation, and maturation of erythroid precursors. At the stage of polychromatic normoblasts, cells were briefly incubated with (59)Fe- and/or (125)I-labeled acid isoferritin and chased. The (125)I-labeled ferritin protein was rapidly degraded and only 50% of the label remained in intact ferritin protein after 3 to 4 hours. In parallel, (59)Fe decreased in ferritin and increased in hemoglobin. Extracellular holoferritin uptake elevated the cellular labile iron pool (LIP) and reduced iron regulatory protein (IRP) activity; this was inhibited by leupeptin or chloroquine. Extracellular apoferritin taken up by the cell functioned as an iron scavenger: it decreased the level of cellular LIP and increased IRP activity. We suggest that the iron from extracellular is metabolized in a similar fashion by developing erythroid cells as is intracellular ferritin. Following its uptake, extracellular ferritin iron is released by proteolytic degradation of the protein shell in an acid compartment. The released iron induces an increase in the cellular LIP and participates in heme synthesis and in intracellular iron regulatory pathways.

Cardioprotective effect of alpha-tocopherol, ascorbate, deferoxamine, and deferiprone: mitochondrial function in cultured, iron-loaded heart cells.

Because mitochondrial inner membrane respiratory complexes are important targets of iron toxicity, we used iron-loaded rat heart cells in culture to study the beneficial effect on mitochondrial enzymes of the iron chelators deferoxamine (DFO) and deferiprone (L1) and of antioxidants and reducing agents (ascorbate and alpha-tocopherol). Reduced nicotinamide adenine dinucleotide-cytochrome c oxidoreductase (complex I-III) and succinate dehydrogenase were the most-sensitive indicators of iron toxicity and cardioprotective effect. Although at concentrations below 0.3 mmol/L the iron-mobilizing effect of L1 was less than that of DFO, both were equally effective in protecting or restoring mitochondrial respiratory enzyme activity. At 1.0 mmol/L, L1 toxicity was manifested in respiratory enzyme inhibition, whereas DFO had no such effect. Ascorbate (0.057 to 5.7 mmol/L) had a mild cardioprotective effect at the highest concentration only, in association with decreased cellular iron uptake. By contrast, alpha-tocopherol (0.023 mmol/L) completely inhibited mitochondrial iron toxicity without affecting iron uptake or release, and irrespective of whether it was used before, during, or after in vitro iron loading. These observations illustrate the usefulness and limitations of iron chelators and other agents used for preventing iron toxicity to the heart and other vital organs, and they underline the need for exploring in more detail the effects of these agents in the clinical setting.

Infective endocarditis due to Stenotrophomonas (Xanthomonas) maltophilia.

Stenotrophomonas maltophilia (formerly Xanthomonas maltophilia) is a gram-negative bacillus increasingly associated with serious nosocomial infections. Here, the case of a 69-year-old female patient who developed prosthetic valve endocarditis associated with this organism is described. A review of the literature revealed only 18 previous reports; eight involved native valves, the remainder prosthetic valves. Most cases were associated with risk factors, including intravenous drug abuse (6 patients), infected intravenous lines (4 patients) or a recent invasive procedure (3 patients). The course of the disease appears to be indolent, but is otherwise similar to infective endocarditis associated with other gram-negative organisms. Antimicrobial therapy is complicated by multiple drug resistance of the organism; cotrimoxazole may be beneficial, if the isolate is susceptible, in combination with another agent. Five of nine (55%) patients who underwent valve replacement survived, as compared to three of seven (43%) who received antibiotic therapy only. Hence, surgery is not essential for survival in every case and depends as much on the individual patient's course as on established criteria for valve replacement in prosthetic valve endocarditis.

Pathophysiology of iron overload.

In thalassemia, iron overload is the joint outcome of excessive iron absorption and transfusional siderosis. While iron absorption is limited by a physiologic ceiling of about 3 mg/d, plasma iron turnover in thalassemia may be 10 to 15 times normal, caused by the wasteful, ineffective erythropoiesis of an enormously expanded erythroid marrow. This outpouring of catabolic iron exceeds the iron-binding capacity of transferrin and appears in plasma as non-transferrin-plasma iron (NTPI). The toxicity of NTPI is much higher than of transferrin-iron as judged by its ability to promote hydroxyl radical formation resulting in peroxidative damage to membrane lipids and proteins. In the heart, this results in impaired function of the mitochrondrial respiratory chain and abnormal energy metabolism manifested clinically in fatal hemosiderotic cardiomyopathy. Ascorbate increases the efficacy of iron chelators by expanding the intracellular chelatable iron pool, but, at suboptimal concentrations is a pro-oxidant, enhancing the catalytic effect of iron in free radical formation. NTPI is removed by i.v. DFO in a biphasic manner and reappears rapidly upon cessation of DFO, lending support to the continuous, rather than intermittent, use of chelators. Unlike DFO and other hexadentate chelators, bidentate chelators such as L1 may produce incomplete intermediate iron complexes at suboptimal drug concentrations.

Mitochondrial respiratory enzymes are a major target of iron toxicity in rat heart cells.

Our previous studies in iron-loaded rat heart cells showed that in vitro iron loading results in peroxidative injury, manifested in a marked decrease in rate and amplitude of heart cell contractility and rhythmicity, which is correctable by treatment with deferoxamine (DF). In the present studies we explored the role of mitochondrial damage in myocardial iron toxicity. Iron loading by 24-hour incubation with 0.36 mmol/L ferric ammonium citrate resulted in a decrease in the activity of nicotinamide adenine dinucleotide (NADH)-cytochrome c oxidoreductase (complex I+III) to 35.3%+/-11.2% of the value in untreated controls; of succinate-cytochrome c oxidoreductase (complex II+III) to 57.4%+/-3.1%; and of succinate dehydrogenase to 63.5%+/-12.6% (p < 0.001 in all cases). The decrease in activity of other mitochondrial enzymes, including NADH-ferricyanide reductase, succinate ubiquinone oxidoreductase (complex II), cytochrome c oxidase (complex IV), and ubiquinol cytochrome c oxidoreductase (complex III), was less impressive and ranged from 71.5%+/-15.8% to 91.5%+/-14.6% of controls. That the observed loss of respiratory enzyme activity was a specific effect of iron toxicity was clearly demonstrated by the complete restoration of enzyme activities by in vitro iron chelation therapy. Sequential treatment with iron and doxorubicin caused a loss of complex I+III and complex II+III activity that was greater than that seen with either agent alone but was only partially correctable by DF treatment. Alterations in cellular adenosine triphosphate measurements paralleled very closely the changes observed in respiratory complex activity. These findings demonstrate for the first time the impairment of cardiac mitochondrial respiratory enzyme activity caused by iron loading at conditions formerly shown to produce severe abnormalities in contractility and rhythmicity.