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.     

Iron chelation therapy

Although iron chelation therapy with deferoxamine (DFO) has changed life expectancy in thalassemic patients, compliance with the rigorous requirements of long-term subcutaneous DFO infusions is unsatisfactory. This problem underlines the current efforts for developing alternative, orally effective chelators to improve compliance and treatment results. For the patient with transfusional iron overload in whom results of DFO treatment are unsatisfactory, several orally effective agents are now available. The most important of the new generation of oral chelators are deferiprone and ICL670. Total iron excretion with deferiprone is less than with DFO, but deferiprone has a better ability to penetrate cell membranes and may have a better cardioprotective effect than DFO. Current studies of the clinical efficacy and tolerability of ICL670 indicate that at a single oral dose of 20 mg/kg daily, it may be as effective as parenteral DFO used at the standard dose of 40 mg/kg daily. Combined chelation treatment, employing a weak chelator that penetrates cells better, and a stronger chelator with efficient urinary excretion, may result in improved therapeutic effect through iron shuttling between the two compounds. The efficacy of combined chelation treatment is additive and offers an increased likelihood of success in patients previously failing DFO or deferiprone monotherapy.     

Normalisation of total body iron load with very intensive combined chelation reverses cardiac and endocrine complications of thalassaemia major

Cardiac and endocrine disorders are common sequelae of iron overload in transfused thalassaemia patients. Combined chelation with desferrioxamine (DFO) and deferiprone (DFP) is well tolerated and produces an additive/synergistic effect superior to either drug alone. 52 thalassaemia major patients were transitioned from DFO to combined chelation with DFO and DFP. Serum ferritin, cardiac and hepatic iron levels were monitored regularly for up to 7 years, as were cardiac and endocrine function. Patients’ iron load normalized, as judged by ferritin and cardiac and hepatic magnetic resonance imaging findings. In all 12 patients receiving treatment for cardiac dysfunction, symptoms reversed following combined chelation, enabling nine patients to discontinue heart medications. In the 39 patients with abnormal glucose metabolism, 44% normalized. In 18 requiring thyroxine supplementation for hypothyroidism, 10 were able to discontinue, and four reduced their thyroxine dose. In 14 hypogonadal males on testosterone therapy, seven stopped treatment. Of the 19 females, who were hypogonadal on DFO monotherapy, six were able to conceive. Moreover, no patients developed de novo cardiac or endocrine complications. These results suggest that intensive combined chelation normalized patients’ iron load and thereby prevented and reversed cardiac and multiple endocrine complications associated with transfusion iron overload.     

Effects of combined deferiprone and deferoxamine chelation therapy on iron load indices in beta-thalassemia

The benefits of combined deferoxamine (DFO) and deferiprone (L1) chelation therapy, focusing on reducing myocardial iron loading, have been widely reported. Herein, we present the efficacy of combined chelation and its effects on iron load indices. Five thalassemia major (TM) patients who were undergoing chelation monotherapy with DFO were enrolled. Inclusion criteria were magnetic resonance imaging (MRI) T2* values, indicating serious heart and/or liver transfusional hemosiderosis. Combined therapy was started with the same dose of DFO and the addition of L1. The MRI T2* studies were repeated 18 months later. An Echo-Doppler study was performed in order to further evaluate the left ventricular (LV) systolic function. Within the 18 months' follow-up period, there was a significant statical decrease in mean serum ferritin levels. All patients increased their MRI T2* liver values, while two patients with very low MRI T2* also increased their myocardial values. The MRI ejection fraction (EF) and Echo-Doppler study measurements confirmed the improvement of systolic function. No adverse effects were reported. Combined L1 and DFO therapy seems to be effective in reducing iron excess in organ iron overloaded thalassemic patients. Magnetic resonance imaging can accurately quantify iron load, while echocardiography remains a reliable monitoring technology.     

Chelation therapy in beta-thalassemia: an optimistic update

Iron chelation therapy with desferrioxamine (DFO) has dramatically improved the outlook in beta-thalassemia. Parenteral DFO reduces tissue iron stores, prevents iron-induced organ damage, and reduces morbidity and mortality, with little serious toxicity. However, the burden of prolonged subcutaneous portable pump infusions, high cost, and patient noncompliance have prompted the development of new methods of administration and new formulations of DFO as well as oral iron chelators. Deferiprone (L1), the only oral iron chelator studied in large long-term clinical trials, is less effective and more toxic than DFO and may not adequately control iron overload; however, compliance and quality of life are improved. Combinations of two iron chelators (such as parenteral DFO plus oral L1, or 2,3-DHB; or oral L1 plus HBED) have been shown to produce additive and synergistic effects, explained by the shuttle hypothesis. Iron bound to a "shuttle"--an oral agent that mobilizes tissue iron--is exchanged in the bloodstream with a "sink"--such as parenteral DFO--and excreted via the kidneys, while the shuttle is reutilized. Combination therapy may produce enhanced iron excretion, target specific iron compartments, minimize side effects, increase treatment options, improve compliance, and facilitate individualization of therapy. Better understanding of the kinetics of iron metabolism, iron overload, and chelation should improve therapeutic strategies.     

Monitoring chelation therapy to achieve optimal outcome in the treatment of thalassaemia

Effective management of iron overload in thalassaemia requires monitoring both for iron toxicity and the effects of excessive chelation. Careful monitoring together with adherence to established regimens using desferrioxamine (DFO) results in a 78% survival rate at 40 years of age at UCLH, with steadily improving survival as progressive cohorts receive chelation earlier in life. By contrast, survival is considerably below this in non-specialist centres. The prognostic significance of the measures being used in monitoring should be known so that decisions about chelation management are evidence-based. Serum ferritin measurement, although easy to perform frequently, is subject to variability and falsely high or falsely low values in relation to body iron are frequently obtained. However, there is evidence that persistently high ferritin values above 2500 microg/l have poor prognostic significance in patients treated with DFO. Liver iron predicts total body iron in a more predictable way than serum ferritin in thalassaemia. Liver iron concentrations of 15 mg/g dry weight appear to predict those patients who develop heart failure in subjects treated with DFO. The prognostic significance of this measurement or indeed other measurements of iron overload in patients treated with other chelation regimens is not known. Recent advances with MRI imaging have aroused interest in its use for monitoring patients with thalassaemia. A recent publication suggests a relationship between left ventricular ejection fraction and cardiac T2*, the value of which shortens with increasing iron concentrations in the liver and hence by inference in the heart. The prognostic value of this technique has not yet been demonstrated in prospective studies and hence changes in therapy based on this measurement alone should be considered with caution at this time. The value of monitoring to decrease morbidity from iron overload is also discussed, particularly with reference to the estimation of iron deposition in the pituitary.     

Effects of Combined Deferiprone and Deferoxamine Chelation Therapy on Iron Load Indices in β-Thalassemia

The benefits of combined deferoxamine (DFO) and deferiprone (L1) chelation therapy, focusing on reducing myocardial iron loading, have been widely reported. Herein, we present the efficacy of combined chelation and its effects on iron load indices. Five thalassemia major (TM) patients who were undergoing chelation monotherapy with DFO were enrolled. Inclusion criteria were magnetic resonance imaging (MRI) T2* values, indicating serious heart and/or liver transfusional hemosiderosis. Combined therapy was started with the same dose of DFO and the addition of L1. The MRI T2* studies were repeated 18 months later. An Echo-Doppler study was performed in order to further evaluate the left ventricular (LV) systolic function. Within the 18 months' follow-up period, there was a significant statical decrease in mean serum ferritin levels. All patients increased their MRI T2* liver values, while two patients with very low MRI T2* also increased their myocardial values. The MRI ejection fraction (EF) and Echo-Doppler study measurements confirmed the improvement of systolic function. No adverse effects were reported. Combined L1 and DFO therapy seems to be effective in reducing iron excess in organ iron overloaded thalassemic patients. Magnetic resonance imaging can accurately quantify iron load, while echocardiography remains a reliable monitoring technology.     

Purging iron from the heart

Methods are now available to measure the magnitude of iron accumulation in the heart. Their validation currently relies on indirect evidence and not on chemical estimation in cardiac biopsies. All patients with symptomatic heart disease appear to have abnormal T2* values, but many patients without symptomatic heart disease also have evidence of increased myocardial iron. Although there is no proof to date that increased myocardial iron, as evidenced by abnormal magnetic resonance imaging, carries an adverse prognosis, it is likely that such new information will affect the chelating programme of patients. In these cases, there are a number of options available: (i) ongoing treatment with either desferrioxamine (DFO) or deferiprone may be intensified; (ii) the patient may be switched to the alternative chelator or (iii) combined chelation with both DFO and deferiprone may be started, which is more effective than using either chelator alone. For patients with symptomatic heart disease, continuous intravenous DFO with, or without deferiprone, remains the currently recommended treatment, in view of its documented ability to salvage these patients.     

Improving survival with deferiprone treatment in patients with thalassemia major: A prospective multicenter randomised clinical trial under the auspices of the Italian Society for Thalassemia and Hemoglobinopathies

The prognosis for thalassemia major has dramatically improved in the last two decades. However, many transfusion-dependent patients continue to develop progressive accumulation of iron. This can lead to tissue damage and eventually death, particularly from cardiac disease. Previous studies that investigated iron chelation treatments, including retrospective and prospective non-randomised clinical trials, suggested that mortality, due mainly to cardiac damage, was reduced or completely absent in patients treated with deferiprone (DFP) alone or a combined deferiprone–deferoxamine (DFP–DFO) chelation treatment. However, no survival analysis has been reported for a long-term randomised control trial. Here, we performed a multicenter, long-term, randomised control trial that compared deferoxamine (DFO) versus DFP alone, sequential DFP–DFO, or combined DFP–DFO iron chelation treatments. The trial included 265 patients with thalassemia major, with 128 (48.3%) females and 137 (51.7%) males.No deaths occurred with the DFP-alone or the combined DFP–DFO treatments. One death occurred due to graft versus host disease (GVHD) in a patient that had undergone bone marrow transplantation; this patient was censored at the time of transplant. Only one death occurred with the DFP–DFO sequential treatment in a patient that had experienced an episode of heart failure one year earlier. Ten deaths occurred with the deferoxamine treatment.The main factors that correlated with an increase in the hazard ratio for death were: cirrhosis, arrhythmia, previous episode of heart failure, diabetes, hypogonadism, and hypothyroidism. In a Cox regression model, the interaction effect of sex and age was statistically significant (p-value < 0.013). For each increasing year of age, the hazard ratio for males was 1.03 higher than that for females (p-value < 0.013).In conclusion, the results of this study show that the risk factors for predicting mortality in patients with thalassemia major are deferoxamine-treatment, complications, and the interaction effect of sex and age.     

Effects of chelation therapy on cardiac function improvement in thalassemia patients: literature review and the Taiwanese experience

The iron chelators deferoxamine (DFO) and deferiprone (L1) have demonstrated their ability to normalize cardiac function in patients with iron overload-induced cardiac disease. However, conventional chelation with subcutaneous DFO fails to prevent iron deposition in two-thirds of thalassemia major patients, placing them at risk of heart failure and its complications. Deferiprone appears to be more effective in cardiac iron removal. The detection and management of heart complications have improved dramatically over the last 7 years. Non invasive techniques of quantifying iron burden via magnetic resonance imaging (MRI) have been validated. A better understanding of cardiac pathophysiology and improved ability to detect at-risk populations are yielding better outcomes and reduced morbidity. We continue to appraise readily available bedside tools for monitoring thalassemia patients with heart complications, and here we summarize studies from the literature and our own findings. Deferiprone chelation was found to be of statistically significant benefit in upgrading cardiac function and reducing iron accumulation. The use of echocardiography and MRI to closely monitor cardiac functions associated with iron overload complications and mortality has proved quite practical.     

Anti-proliferative effect of interferon-gamma is enhanced by iron chelation in colon cancer cell lines in vitro

BACKGROUND/AIMS: The receptor of interferon-gamma (IFN-gammaR) consists of IFN-gammaR1 and R2. Resistance to the anti-proliferative effect of IFN-gamma is due to downregulation of IFN-gammaR2. The aim of this study was to investigate whether iron chelation could upregulate IFN-gammaR2 and enhance the anti-proliferative effect of IFN-gamma in colon cancer cell lines. METHODOLOGY: The colon cancer cell lines, SW480, COLO, and WiDr were treated with the iron chelating agent DFO, and the expression of IFN-gammaR1 and IFN-gammaR2 was evaluated by FACS. The anti-proliferative effect of IFN-gamma was investigated by MTT assay, and the proapoptotic effect was investigated by FACS with Annexin-V. RESULTS: FACS demonstrated that DFO increased the expression of IFN-gammaR2, whereas the effect on IFN-gammaR1 expression was less marked. MTT assay showed that cell growth was inhibited by DFO. Addition of DFO and IFN-gamma inhibited further, but inhibition was not observed with IFN-gamma alone. Apoptotic cells were increased by DFO, and further increased with DFO + IFN-gamma together. CONCLUSIONS: Expression of IFN-gammaR2 is restored by iron chelation, and the increased expression of IFN-gammaR2 enhances the anti-proliferative effect of IFN-gamma through induction of apoptosis in colon cancer cells.     

The proceedings of the 19Th international conference on chelation held in London, United Kingdom: major changes in iron chelation therapy in the last 25 years using deferiprone (L1) has resulted in the complete treatment of iron overload

Major advances were presented at the 19th International Conference on Chelation (ICOC) in London, UK including changes in iron chelation therapy that led to the complete treatment of transfusional iron overload. The first oral iron chelation results in animals using deferiprone (L1) were published in 1985, and effective iron removal in thalassemia and myelodysplasia patients were reported 2 years later. The results of multicenter clinical trials of L1 were presented at the 1st ICOC in London, UK in 1989. Long-term use of L1 resulted in the reduction of the mortality rate in thalassemia patients due to the effective removal of all excess iron from the heart. In 2008, specific combinations of L1 and deferoxamine (DFO) were reported to cause the complete removal of excess iron load and the achievement of normal range body iron store levels (NRBISL) in thalassemia patients. Patients with NRBISL were identified to require lower doses of L1 for the maintenance of negative iron balance. The introduction of deferasirox (DFRA) may benefit patients not tolerating L1, DFO or their combination. A simple, inexpensive synthesis of L1 has encouraged its manufacture in developing countries for the benefit of patients who could not afford the expensive imported chelating drugs or formulations.     

The effect of desferrioxamine chelation versus no therapy in patients with non transfusion-dependent thalassaemia: a multicenter prospective comparison from the MIOT network

We prospectively assessed by magnetic resonance imaging (MRI) the advantages of desferrioxamine (DFO) with respect to the absence of chelation therapy in non transfusion-dependent thalassaemia (NTDT) patients. We considered 18 patients non-chelated and 33 patients who received DFO alone between the two MRI scans. Iron overload was assessed by the T2* technique. Biventricular function parameters were quantified by cine sequences. No patient treated with DFO had cardiac iron. At baseline, only one non-chelated patient showed a pathological heart T2* value (<?20 ms) and he recovered at the follow-up. The percentage of patients who maintained a normal heart T2* value was 100% in both groups. A significant increase in the right ventricular ejection fraction was detected in DFO patients (3.48?±?7.22%; P?=?0.024). The changes in cardiac T2* values and in the biventricular function were comparable between the two groups. In patients with hepatic iron at baseline (MRI liver iron concentration (LIC)?≥?3 mg/g/dw), the reduction in MRI LIC values was significant only in the DFO group (??2.20?±?4.84 mg/g/dw; P?=?0.050). The decrease in MRI LIC was comparable between the groups. In conclusion, in NTDT patients, DFO therapy showed no advantage in terms of cardiac iron but its administration allowed an improvement in right ventricular function. Moreover, DFO reduced hepatic iron in patients with significant iron burden at baseline.     

Effects of Chelation Therapy on Cardiac Function Improvement in Thalassemia Patients: Literature Review and the Taiwanese Experience

The iron chelators deferoxamine (DFO) and deferiprone (L1) have demonstrated their ability to normalize cardiac function in patients with iron overload-induced cardiac disease. However, conventional chelation with subcutaneous DFO fails to prevent iron deposition in two-thirds of thalassemia major patients, placing them at risk of heart failure and its complications. Deferiprone appears to be more effective in cardiac iron removal. The detection and management of heart complications have improved dramatically over the last 7 years. Non invasive techniques of quantifying iron burden via magnetic resonance imaging (MRI) have been validated. A better understanding of cardiac pathophysiology and improved ability to detect at-risk populations are yielding better outcomes and reduced morbidity.

We continue to appraise readily available bedside tools for monitoring thalassemia patients with heart complications, and here we summarize studies from the literature and our own findings. Deferiprone chelation was found to be of statistically significant benefit in upgrading cardiac function and reducing iron accumulation. The use of echocardiography and MRI to closely monitor cardiac functions associated with iron overload complications and mortality has proved quite practical.     

Deferoxamine infusion does not inhibit bleomycin-induced lung damage in the rat

It has been proposed that the pneumonitis and subsequent lung fibrosis induced by bleomycin occurs when bleomycin is complexed with ferrous iron and oxygen. In order to see whether chelation of free iron reduced tissue damage induced by intratracheal bleomycin, deferoxamine (DFO) was administered by continuous subcutaneous infusion to overcome its rapid renal excretion. Thirty-three rats received DFO and 30 rats received an equivalent volume of saline by 7-day infusion pumps. Three days after commencement of infusion, half of each group received intratracheal bleomycin, the remainder received intratracheal saline. Three weeks after intratracheal injection, the rats were killed and their lungs were removed for histologic and morphometric assessment and collagen estimation. When compared with animals given intratracheal saline, both bleomycin-treated groups had significant evidence of lung toxicity, but DFO was not protective. Similarly, DFO infusion did not reduce the elevation in collagen concentration (bleomycin/saline, 49 +/- 3.6; bleomycin/DFO, 49.8 +/- 4.1; saline/saline, 39.6 +/- 3.9; saline/DFO, 43.4 +/- 3.8 mg.g-1 wet lung weight) or total lung collagen (bleomycin/saline, 29.9 +/- 6.3; bleomycin/DFO, 33.7 +/- 1.8; saline/saline, 15.5 +/- 2.2; saline/DFO, 17.8 +/- 1.9 mg.left lung-1) induced by bleomycin. This lack of effect was not due to iron contamination of the DFO in the pump or to loss of chelation capacity of DFO, at least for as long as 6 days after pump implantation. No DFO was detected in homogenized lung tissue (limits of detection of assay was 8 x 10(-5) M).(ABSTRACT TRUNCATED AT 250 WORDS)     

Sequential alternating deferiprone and deferoxamine treatment compared to deferiprone monotherapy: main findings and clinical follow-up of a large multicenter randomized clinical trial in -thalassemia major patients

In β-thalassemia major (β-TM) patients, iron chelation therapy is mandatory to reduce iron overload secondary to transfusions. Recommended first line treatment is deferoxamine (DFO) from the age of 2 and second line treatment after the age of 6 is deferiprone (L1). A multicenter randomized open-label trial was designed to assess the effectiveness of long-term alternating sequential L1-DFO vs. L1 alone iron chelation therapy in β-TM patients. Deferiprone 75 mg/kg 4 days/week and DFO 50 mg/kg/day for 3 days/week was compared with L1 alone 75 mg/kg 7 days/week during a 5-year follow-up. A total of 213 thalassemia patients were randomized and underwent intention-to-treat analysis. Statistically, a decrease of serum ferritin level was significantly higher in alternating sequential L1-DFO patients compared with L1 alone patients (p = 0.005). Kaplan-Meier survival analysis for the two chelation treatments did not show statistically significant differences (log-rank test, p = 0.3145). Adverse events and costs were comparable between the groups. Alternating sequential L1-DFO treatment decreased serum ferritin concentration during a 5-year treatment by comparison to L1 alone, without significant differences of survival, adverse events or costs. These findings were confirmed in a further 21-month follow-up. These data suggest that alternating sequential L1-DFO treatment may be useful for some β-TM patients who may not be able to receive other forms of chelation treatment.     

Incidence of Ototoxicity in Pediatric Patients with Transfusion-Dependent Thalassemia Who Are Less Well-Chelated by Mono- and Combined Therapy of Iron Chelating Agents

Ototoxicity due to iron chelation therapy, especially deferoxamine (DFO), is frequently observed in patients who have a higher chelation index (>0.025). However, there is limited data on patients who are less well-chelated and on other chelating regimens, including deferiprone (L1), deferasirox (DFX), and a combination of DFO and L1. To determine the incidence of ototoxicity from iron chelators, we retrospectively analyzed our clinical records from January 1997 to December 2010. All transfusion-dependent thalassemia (TDT) patients received iron chelation therapy with mono DFX, DFO, L1, or a combination. All patients underwent routine otolaryngologic examination and pure-tone audiometry before starting each chelation regimen and were regularly followed every 6 months. One hundred thalassemic patients were enrolled and analyzed (48 males and 52 females), with a mean age of 12.11?±?4.48 years (range 2.5–22.5 years). Total summative duration of iron chelation therapy in all patients was 596.50 years. Nine patients were found to have conductive hearing loss. Sensorineural hearing loss (SNHL) was identified in seven patients but only four were determined to be associated with iron chelators; three patients were detected while undergoing DFO therapy and one patient with L1 therapy. None of patients undergoing DFO therapy had reached over the levels of chelation index. In our resource-limited setting with poor treatment compliance, there was a rather low incidence of ototoxicity after exposure to iron chelators. However, a routine audiometry remains recommended for early detection and intervention since SNHL still develops and results in a long-term morbidity.     

A New Era in Iron Chelation Therapy: The Design of Optimal,Individually Adjusted Iron Chelation Therapies for the Complete Removal of Iron Overload in Thalassemia and other Chronically Transfused Patients

A new era in iron chelation therapy began with the successful removal of excess iron load and the maintenance of normal iron stores in thalassemia patients using the International Committee on Chelation (ICOC) protocols. This achievement was based on two phases, firstly the introduction of deferiprone (L1) (80–100 mg/kg/day) and deferoxamine (DFO) (40–60 mg/kg at least 3 days per week) combination therapy, which appears to progressively remove all excess storage iron and thereafter by the introduction of L1 monotherapy that can maintain physiological range levels of serum ferritin, cardiac and liver magnetic resonance imaging (MRI) T2*. This new development is likely to change current practices and set a new gold standard in the treatment of transfusional iron loaded patients leading to an increased survival and the change of thalassemia from a fatal to a chronic disease. A major aspect of the improved therapies is the ability of L1 to mobilize and remove excess cardiac iron and reduce congestive cardiac failure, which is the main cause of death in thalassemia patients. Further, new developments include the use of alternating sequential chelation therapies and selected dose protocols with L1, DFO and deferasirox (DFRA) for overcoming toxicity and efficacy complications observed in some patients treated with monotherapies or combination therapies. The selection and adjustment of dose protocols is crucial for providing optimum chelation therapy for each individual patient.     

Is growth hormone deficiency contributing to heart failure in patients with beta-thalassemia major?

A 21-year-old woman with beta-thalassemia major (beta-TM) and GH deficiency developed end-stage heart failure, New York Heart Association (NYHA) functional class IV, within 3 months after withdrawal of recombinant human growth hormone (GH). A myocardial biopsy excluded myocarditis and showed moderate iron deposit in the heart. Before her admission, intensified treatments with digoxin, angiotensin-converting enzyme inhibitor, diuretics and extra chelation therapy (desferrioxamine (DFO)) had not improved her progressive heart failure. At admission, GH was reinstituted together with intensified treatment of cardiac drugs and low doses of DFO, and her heart failure reversed. Four months later, NYHA functional class II was reached and within 1 year her cardiac function was normalised. We suggest that GH deficiency due to iron-induced damage to the hypothalamic-pituitary axis can contribute to heart failure in adult patients with beta-TM.     

Identification of the Asymmetric Hybrid of Human Oxy Hemoglobins A and S (α2βAβS) at 4° C by Cellulose Acetate Electrophoresis

Millions of people are affected by hereditary hemochromatosis (HH) and thalassemia intermedia (TI), the iron overloading disorders caused by chronic increases in iron absorption. Genetic factors, regulatory pathways involving proteins of iron metabolism, non regulatory molecules, dietary constituents and iron binding drugs could affect iron absorption and could lead to iron overload or iron deficiency. Chelators and chelating drugs can affect both iron absorption and excretion. Deferoxamine (DFO), deferiprone (L1) and the DFO/L1 combination therapies have been used effectively for reversing the toxic side effects of iron overload including cardiac and liver damage in TI and HH patients where venesection is contraindicated. Selected protocols using DFO, L1 and their combination could be designed for optimizing chelation therapy in TI and HH. The use of deferasirox (DFRA) in HH and TI could cause an increase in iron and other toxic metal absorption. Future treatments of HH and TI could involve the use of iron chelating and other drugs not only for increasing iron excretion but also for preventing iron absorption.