Deferasirox treatment improved the hemoglobin level and decreased transfusion requirements in four patients with the myelodysplastic syndrome and primary myelofibrosis

Transfusion-induced iron overload is a frequent problem that clinicians have to face in the treatment of patients affected by both myelodysplastic syndrome (MDS) and primary myelofibrosis (PMF). Different options are currently available for chelation therapy, e.g. oral once-daily administration of the iron chelator deferasirox. In 3 patients with MDS and 1 patient with PMF, deferasirox therapy resulted in an improvement in the hemoglobin level and a reduction in transfusion dependence. Our data open new insights regarding the benefit of iron chelation therapy not only for transfusional iron overload of myelodysplastic and myelofibrotic patients but also for the increase in hemoglobin levels. The biological mechanism of action of deferasirox, an effect which is not shared by other iron chelators, is still obscure and requires further investigations.     

Evaluation of cardiac and hepatic iron overload in thalassemia major patients with T2* magnetic resonance imaging

Objectives: Recent advancements have promoted the use of T2* magnetic resonance imaging (MRI) in the non-invasive detection of iron overload in various organs for thalassemia major patients. This study aims to determine the iron load in the heart and liver of patients with thalassemia major using T2* MRI and to evaluate its correlation with serum ferritin level and iron chelation therapy.

Methods: This cross-sectional study included 162 subjects diagnosed with thalassemia major, who were classified into acceptable, mild, moderate, or severe cardiac and hepatic iron overload following their T2* MRI results, respectively, and these were correlated to their serum ferritin levels and iron chelation therapy.

Results: The study found that 85.2% of the subjects had normal cardiac iron stores. In contrast, 70.4% of the subjects had severe liver iron overload. A significant but weak correlation (r?=??0.28) was found between cardiac T2* MRI and serum ferritin, and a slightly more significant correlation (r?=?0.37) was found between liver iron concentration (LIC) and serum ferritin.

Discussion: The findings of this study are consistent with several other studies, which show that patients generally manifest with liver iron overload prior to cardiac iron overload. Moreover, iron accumulation demonstrated by T2* MRI results also show a significant correlation to serum ferritin levels.

Conclusion: This is the first study of its kind conducted in Indonesia, which supports the fact that T2* MRI is undoubtedly valuable in the early detection of cardiac and hepatic iron overload in thalassemia major patients.     

Japanese epidemiological survey with consensus statement on Japanese guidelines for treatment of iron overload in bone marrow failure syndromes

Many patients with bone marrow failure syndromes need frequent transfusions of red blood cells, and most of them eventually suffer from organ dysfunction induced by excessively accumulated iron. The only way to treat transfusion-induced iron overload is iron chelating therapy. However, most patients have not been treated effectively because daily/continuous administration of deferoxamine is difficult for outpatients. Recently, a novel oral iron chelator, deferasirox, has been developed, and introduction of the drug may help many patients benefit from iron chelation therapy. In this review, we will discuss the current status of iron overload in transfusion-dependent patients, and the development of Japanese guidelines for the treatment of iron overload in Japan, which were established by the National Research Group on Idiopathic Bone Marrow Failure Syndromes in Japan.     

Combined therapy with desferrioxamine and deferiprone in beta thalassemia major patients with transfusional iron overload

Iron overload is the main cause of morbidity and mortality especially from heart failure in patients with beta thalassemia major (TM). Successful iron chelation is therefore essential for the optimal management of TM. Although desferrioxamine (DFX) has been the major iron-chelating treatment of transfusional iron overload, compliance is a major hindrance in achieving optimal therapeutic results. The availability of oral iron chelation with deferiprone (L₁) since 1987 is useful but showed poor efficacy when used alone as compared to DFX. We therefore decided to compare DFX alone with a prospective combined therapy with DFX and L₁ in beta thalassemia major patients with iron overload. We studied 91 patients with beta thalassemia major (mean age±SD, 15.02±5.8; range 2–30 years) attending the day care unit for regular transfusional support. They received packed red cells every 3–4 weeks to maintain pretransfusion hemoglobin concentration above 9 g/dl. They had been receiving DFX at a daily dose of 40 mg kg⁻¹ day⁻¹ by subcutaneous infusion for 8–10 h on 4–5 nights each week for the past several years. However, due to various reasons, they had developed considerable transfusional iron overload. These patients were allocated to prospectively receive additional therapy with oral iron chelator L₁ at 75 mg kg⁻¹ day⁻¹ body weight in three divided doses with food after informed consent and continued to receive treatment with DFX as per the above dosage. Of the 91 patients, six developed severe gastrointestinal (GI) upset, two agranulocytosis, two arthropathy, one persistently raised liver enzymes, two died owing to sepsis, and two received allogeneic bone marrow transplantation. Amongst the remaining 76 patients, 21 were found noncompliant (not taking DFX regularly, but taking L₁ regularly). Thus, in the 55 evaluable patients {6–48 months on combination therapy; mean [(±SD)22±12 months]}, the mean serum ferritin (±SD) fell dramatically from 3,088 (±1,299) ng/ml (DFX alone) to 2,051 (±935) ng/ml (DFX and L₁; p<0.001). It is interesting to note that there was also a significant improvement in the myocardial function as assessed by the ejection fraction (p<0.004) and fractional shortening (p<0.05) in those patients (n=42) who could be studied after being on combination therapy for a minimum of 1 year. The study emphasizes that beta thalassemia major patients with transfusional iron overload can be successfully treated with a combination of DFX and L₁. Our results also demonstrate a significant statistical improvement after as little as 6 months of combination therapy. Furthermore, these improvements lead to a progressive fall in the mean serum ferritin. Lastly, the study also demonstrates significant improvement in the echocardiographic parameters of myocardial performance in these patients receiving combination therapy.     

Hepcidin response to acute iron intake and chronic iron loading in dysmetabolic iron overload syndrome

Background: The pathogenesis of dysmetabolic iron overload syndrome (DIOS) is still unclear. Hepcidin is the key regulator of iron homeostasis controlling iron absorption and macrophage release. Aim: To investigate hepcidin regulation by iron in DIOS. Methods: We analysed urinary hepcidin at baseline and 24 h after a 65 mg oral iron dose in 24 patients at diagnosis and after iron depletion (n=13) and compared data with those previously observed in 23 healthy controls. Serum iron indices, liver histology and metabolic data were available for all patients. Results: At diagnosis, hepcidin values were significantly higher than in controls (P<0.001). After iron depletion, hepcidin levels decreased to normal values in all patients. At baseline, a significant response of hepcidin to iron challenge was observed only in the subgroup with lower basal hepcidin concentration (P=0.007). In iron‐depleted patients, urinary hepcidin significantly increased after oral iron test (P=0.006). Conclusions: Ours findings suggest that in DIOS, the progression of iron accumulation is counteracted by the increase in hepcidin production and progressive reduction of iron absorption, explaining why these patients develop a mild–moderate iron overload that tends to a plateau.     

The global burden of iron overload

There have been major developments in the field of iron metabolism in the past decade following the identification of the HFE gene and the mutation responsible for the C282Y substitution in the HFE protein. While HFE-associated hemochromatosis occurs predominantly in people of northern European extraction, other less-common mutations can lead to the same clinical syndrome and these may occur in other populations in the Asian-Pacific region. The most common of these is the mutation that leads to changes in the ferroportin molecule, the protein responsible for the transport of iron across the basolateral membrane of the enterocyte and from macrophages. Recent research has unraveled the molecular processes of iron transport and regulation of how these are disturbed in hemochromatosis and other iron-loading disorders. At the same time, at least one new oral iron chelating agent has been developed that shows promise in the therapy of hemochromatosis as well as thalassemia and other secondary causes of iron overload. It is pertinent therefore to examine the developments in the global field of iron overload that have provided insights into the pathogenesis, disease penetrance, comorbid factors, and management.     

Iron chelation therapy in the myelodysplastic syndromes and aplastic anemia: a review of experience in South Korea

Emerging clinical data indicate that transfusion-dependent patients with bone marrow-failure syndromes (BMFS) are at risk of the consequences of iron overload, including progressive damage to hepatic, endocrine, and cardiac organs. Despite the availability of deferoxamine (DFO) in Korea since 1998, data from patients with myelodysplastic syndromes, aplastic anemia, and other BMFS show significant iron overload and damage to the heart and liver. The recent introduction of deferasirox, a once-daily, oral iron chelator, may improve the availability of iron chelation therapy to iron-overloaded patients, and improve compliance in patients who may otherwise find adherence to the DFO regimen difficult.     

Current status of iron chelation therapy with deferoxamine

Long-term chelation therapy with deferoxamine is an effective and generally safe method for removing excessive iron, preventing iron-induced organ damage and improving survival of patients with transfusion-dependent disorders. The current treatment of iron overload is an important standard against which new forms of therapy, such as oral chelators, should be measured to ensure that their risks and benefits compare favorably with deferoxamine. Until new treatments are available, continuing studies of deferoxamine will help to define its long-term efficacy and toxicity for patients with thalassemia major and other hematologic disorders.     

Iron overload and allogeneic hematopoietic stem-cell transplantation

Iron overload is frequently observed in patients with hematologic diseases before and after allogeneic stem-cell transplantation because they usually receive multiple red blood cell transfusions. Elevated pretransplant serum ferritin levels, which are widely used as indicators of body iron status, are significantly associated with a lower overall survival rate and a higher incidence of treatment-related complications; for example, infections and hepatic veno-occlusive disease. As serum ferritin levels are affected, not only by iron loading but also by inflammation, imaging techniques to quantify tissue iron levels have been developed, for example, quantitative MRI using the transverse magnetic relaxation rate, and superconducting quantum interference devices. Iron chelators, such as deferasirox, a new oral iron-chelating agent, reduce iron load in transfusion-dependent patients. Iron-chelating therapy before and/or after transplantation is a promising strategy to improve the clinical outcomes of transplant patients with iron overload. However, further research is needed to prove the direct relationship between iron overload and adverse outcomes, as well as to determine the effects of treatment for iron overload on outcomes of allogeneic stem-cell transplantation.     

Pituitary iron and volume predict hypogonadism in transfusional iron overload

Hypogonadism is the most common morbidity in patients with transfusion‐dependent anemias such as thalassemia major. We used magnetic resonance imaging (MRI) to measure pituitary R2 (iron) and volume to determine at what age these patients develop pituitary iron overload and volume loss. We recruited 56 patients (47 with thalassemia major, five with chronically transfused thalassemia intermedia and four with Blackfan‐Diamond syndrome) to have pituitary MRIs to measure pituitary R2 and volume. Hypogonadism was defined clinically based on the timing of secondary sexual characteristics or the need for sex hormone replacement therapy. Patients with transfusional iron overload begin to develop pituitary iron overload in the first decade of life; however, clinically significant volume loss was not observed until the second decade of life. Severe pituitary iron deposition (Z > 5) and volume loss (Z < ?2.5) were independently predictive of hypogonadism. Pituitary R2 correlated significantly with serum ferritin as well as liver, pancreatic, and cardiac iron deposition by MRI. Log pancreas R2* was the best single predictor for pituitary iron, with an area under the receiving operator characteristic curve of 0.88, but log cardiac R2* and ferritin were retained on multivariate regression with a combined r² of 0.71. Pituitary iron overload and volume loss were independently predictive of hypogonadism. Many patients with moderate‐to‐severe pituitary iron overload retained normal gland volume and function, representing a potential therapeutic window. The subset of hypogonadal patients having preserved gland volumes may also explain improvements in pituitary function observed following intensive chelation therapy. Am. J. Hematol. 2011. © 2011 Wiley Periodicals, Inc.     

Combination therapy with a Tmprss6 RNAi‐therapeutic and the oral iron chelator deferiprone additively diminishes secondary iron overload in a mouse model of β‐thalassemia intermedia

β‐thalassemias result from diminished β‐globin synthesis and are associated with ineffective erythropoiesis and secondary iron overload caused by inappropriately low levels of the iron regulatory hormone hepcidin. The serine protease TMPRSS6 attenuates hepcidin production in response to iron stores. Hepcidin induction reduces iron overload and mitigates anemia in murine models of β‐thalassemia intermedia. To further interrogate the efficacy of an RNAi‐therapeutic downregulating Tmprss6, β‐thalassemic Hbb^th3/+ animals on an iron replete, an iron deficient, or an iron replete diet also containing the iron chelator deferiprone were treated with Tmprss6 siRNA. We demonstrate that the total body iron burden is markedly improved in Hbb^th3/+ animals treated with siRNA and chelated with oral deferiprone, representing a significant improvement compared to either compound alone. These data indicate that siRNA suppression of Tmprss6, in conjunction with oral iron chelation therapy, may prove superior for treatment of anemia and secondary iron loading seen in β‐thalassemia intermedia. Am. J. Hematol. 90:310–313, 2015. © 2015 The Authors. American Journal of Hematology Published by Wiley Periodicals, Inc.     

Correction of anemia in a transfusion-dependent patient with primary myelofibrosis receiving iron chelation therapy with deferasirox (Exjade, ICL670)

Transfusional iron overload in patients with chronic anemias can result in multiple organ failure. Experience in the management of iron overload in patients with myelodysplastic syndromes is limited, as many do not receive chelation therapy due to short-life expectancy and the difficulties associated with the administration of the current reference standard chelator, deferoxamine. There have, however, been some reports of reduced transfusion requirement associated with chelation therapy in patients with myelodysplastic syndromes and myelofibrosis. Here, we discuss a patient with primary myelofibrosis and related transfusion-dependent anemia who received chelation therapy with the once-daily oral iron chelator, deferasirox. In addition to the reduced iron levels, the patient demonstrated an unexpected reduction in blood transfusion requirement, ultimately resulting in long-lasting transfusion-free survival.     

Microarray analysis of liver gene expression in iron overloaded patients with sickle cell anemia and beta‐thalassemia

Chronic transfusion therapy is used clinically to supply healthy erythrocytes for patients with sickle cell anemia (SCA) or beta‐thalassemia major (TM). Despite the benefits of red blood cell transfusions, chronic transfusions lead to iron accumulation in key tissues such as the heart, liver, and endocrine glands. Transfusion‐acquired iron overload is recognized as a cause of morbidity and mortality among patients receiving chronic transfusions. At present, there is little understanding of molecular events that occur during transfusional iron loading and the reasons for the large inter‐individual variation observed clinically in transfusion‐acquired iron accumulation. To address these issues, we examined whether any liver‐expressed genes in SCA or TM patients with transfusional iron overload were associated with the degree of iron accumulation. Specifically, we performed microarray analysis on liver biopsy specimens comparing SCA patients with mild or severe iron overload and also compared SCA with TM patients. Fifteen candidate genes were identified with significantly differential expression between the high and low liver iron concentrations. SCA patients and 20 candidate genes were detected between the SCA and TM patient comparison. Subsequent quantitative PCR experiments validated 12 candidate genes; with GSTM1, eIF5a, SULF2, NTS, and HO‐1 being particularly good prospects as genes that might affect the degree of iron accumulation. Future work will determine the baseline expression of these genes prior to transfusional iron overload and elucidate the full impact of these genes on the inter‐individual variation observed clinically in transfusion‐acquired iron accumulation. Am. J. Hematol. 2009. © 2009 Wiley‐Liss, Inc.     

Management of high ferritin in long-term survivors after hematopoietic stem cell transplantation

Management of high serum ferritin levels after allogeneic hematopoietic stem cell transplantation (allo-HSCT) should, from the diagnostic standpoint, be based on the pathophysiological mechanisms underlying the development of hyperferritinemia. This knowledge is essential for differentiating increased serum ferritin due to iron overload from "non-iron overload" situations such as inflammation, metabolic syndrome, or hepatitis. Once body iron overload has been proven, especially by quantifying tissue iron excess with the noninvasive magnetic resonance imaging (MRI) method, it is important, considering the damaging effects of chronic iron overload in these patients, to start iron depletive therapy by oral chelation or phlebotomy. At present, more data are needed to assess the long-term deleterious effects of iron excess in the HSCT population, and to define the most appropriate therapeutic strategy for removing iron burden. Also, preventing iron overload prior to HSCT might prove essential for improving patient prognosis through decreasing HSCT-related mortality.     

Iron Mobilization From Transferrin And Non-Transferrin-Bound-Iron by Deferiprone. Implications in the Treatment of Thalassemia,Anemia of Chronic Disease,Cancer and Other Conditions

Iron mobilization from transferrin is one of the most important screening methods for the selection of chelators intended for clinical use in the treatment of iron overload in thalassemia and other conditions. In vitro and in vivo screening of approved and experimental chelating drugs has shown that only the α-ketohydroxypyridines deferiprone (L1) and 1-allyl-2 methyl-3-hydroxypyrid-4-one (L1NAll), are effective in the mobilization of iron from transferrin. Iron mobilization from transferrin and non-transferrin-bound-iron (NTBI) can be used to optimize existing chelation therapy protocols for the treatment of iron loaded patients. New chelation strategies involving L1 and its combination with deferoxamine (DFO) and other chelators can be used to increase iron excretion and reduce or prevent excess iron deposition in the heart and other vital organs of iron loaded patients by comparison to monotherapies. Deferiprone and its combinations may also have potential applications in the treatment of cancer, the anemia of chronic disease and other conditions.     

Long-term improvement in cardiac magnetic resonance in β-thalassemia major patients treated with deferasirox extends to patients with abnormal baseline cardiac function

The management of iron overload in thalassemia has changed dramatically since the implementation of magnetic resonance imaging, which allows detection of preclinical iron overload and prevention of clinical complications. This study evaluated the effect of deferasirox (DFX), the newest once-daily oral chelator, on cardiac function, iron overload and cardiovascular events over a longer follow up in a “real world” setting. Longitudinal changes in cardiac magnetic resonance T2*, cardiac function parameters and cardiovascular clinical events were assessed in a cohort of 98 TM patients exposed to DFX for a mean of 6.9 years (range 1.8-11.6 years). No cardiac death or incident heart failure occurred. Cardiac T2* significantly increased (+2.6 ± 11.9 msec; P = 0.035) in the whole population, with a significantly greater increase (+11.6 ± 15.5 msec, P = 0.019) in patients with cardiac iron overload (T2* <20 ms). A significant improvement in left-ventricular ejection fraction (LVEF) (from 50.6 ± 6 to 60.2 ± 5; P = 0.001) was observed in 11 (84.6%) out of 13 patients who normalized cardiac function (LVEF >56%). Arrhythmias were the most frequent cardiac adverse event noted but none led to DFX discontinuation. Our data indicate that DFX is effective in maintaining cardiac iron level in the normal range and in improving cardiac iron overload. No heart failure or cardiac death was reported over this longer observation up to 12 years. For the first time, a DFX-induced improvement in LVEF was observed in a subgroup of patients with abnormal cardiac function at baseline, a preliminary observation which deserves further evaluation.     

Guidelines for treating iron overload in myelodysplastic syndromes: a Taiwan consensus statement

Iron overload is common in myelodysplastic syndrome (MDS) patients, and an accumulation of evidence shows that iron chelation may have benefits in these patients. However, discussion and consensus about iron chelation therapy (ICT) for MDS patients is lacking in Taiwan and other Southeast Asian countries. An Expert Panel in Taiwan was organized in 2011 to develop iron overload guidelines and provide a uniform reference for physicians treating MDS patients with iron overload, with specific regard to when to initiate ICT, in which patients, and the clinical and scientific rationale behind its use.     

Estimation of cardiac left ventricular ejection fraction in transfusional cardiac iron overload by R2* magnetic resonance

Cardiac dysfunction due to transfusional iron overload is one of the most critical complications for patients with transfusion-dependent hematological disorders. Clinical parameters such as total red blood cell (RBC) transfusion units and serum ferritin level are usually considered as indicators for initiation of iron chelation therapy. We used MRI-T2*, MRI-R2* values, and left ventricular ejection fraction in 19 adult patients with blood transfusion-dependent hematological disorders without consecutive oral iron chelation therapy, and propose possible formulae of cardiac function using known parameters, such as total RBC transfusion units and serum ferritin levels. We found a positive correlation in all patients between both R2* values (reciprocal values of T2*) and serum ferritin levels (r = 0.81) and also total RBC transfusion volume (r = 0.90), but not when we analyzed subgroups of patients whose T2* values were over 30 ms (0.52). From the formulae of the R2*, we concluded that approximately 50 Japanese units or 2,900 pmol/L ferritin might be the cutoff value indicating possible future cardiac dysfunction.     

Long-term efficacy of deferoxamine iron chelation therapy in adults with acquired transfusional iron overload

Transfusional iron overload in adult patients with acquired anemias may result in widespread organ dysfunction. Long-term deferoxamine mesylate therapy was administered by continuous subcutaneous infusion to six such patients, who have been followed up for up to 66 months of therapy while continuing to be transfusion-dependent. During deferoxamine therapy, liver density by computed tomographic scan decreased in four of five patients, liver iron content decreased in two of three patients, and liver function normalized in two patients. Plasma cortisol response to insulin-induced hypoglycemia improved in three of five patients receiving therapy. Pituitary growth hormone reserve normalized in two patients and remained normal in the other three tested. One patient, treated concurrently with ascorbic acid, died suddenly. The other five patients have had no cardiac deterioration by noninvasive testing. We conclude that long-term deferoxamine iron chelation therapy is effective not only in retarding but, in some cases, even reversing organ damage caused by transfusional iron overload.     

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.