Myocyte damage and loss of myofibers is the potential mechanism of iron overload toxicity in congestive cardiac failure in thalassemia. Complete reversal of the cardiomyopathy and normalization of iron load by deferiprone

Cardiac damage caused by iron overload toxicity is the main cause of death in thalassemia patients. Biopsy samples of poorly chelated thalassemia patients who suffered congestive cardiac failure (CCF) show extensive iron deposition in the myocardium. In one patient who survived CCF, a cardiac biopsy was performed during the removal of a thrombus caused by a port-a-cath, which was used for the administration of intravenous (iv) deferoxamine (DFO). Ultrastructural pathology studies of the cardiac biopsy indicated extensive iron deposition in myocytes with accumulation of iron mainly in lysosomes, leading in some cases to their disruption. Damage to other intracellular components of the myocytes and loss of myofibers was also observed. The patient became intolerant to iv and subcutaneous (sc) DFO 2 years after the CCF, and was then treated with deferiprone (L1) for 7 years. Within 1 year of L1 treatment at 75-80 mg/kg/day, serum ferritin levels were reduced to <0.45 mg/L and she became asymptomatic, needing no further drugs for her cardiomyopathy. Lowering the L1 dose to 50-70 mg/kg/day caused an increase in serum ferritin levels. Maintenance of normal iron stores during the last 3 years as detected by cardiac and liver magnetic resonance imaging (MRI) T2 and T2* and normalization of serum ferritin levels (<0.15 mg/L) was observed following L1 therapy at 80-85 mg/kg/day. Deferiprone (>80 mg/kg/day) appears to be effective in the rapid clearance of cardiac iron, in the reversal of iron overload related cardiomyopathy, in the maintenance of normal iron stores and the overall long-term survival of thalassemia patients.     

Low Serum Ferritin Levels are Misleading for Detecting Cardiac Iron Overload and Increase the Risk of Cardiomyopathy in Thalassemia Patients. The Importance of Cardiac Iron Overload Monitoring Using Magnetic Resonance Imaging T2 and T2*

The incidence of cardiomyopathy was monitored in a 6-year follow-up study involving 56 transfused thalassemia patients treated with deferoxamine (DFO), deferiprone (L1) or their combination. During this period, five female patients on regular subcutaneous or intravenous DFO presented with cardiac complications. Three patients suffered congestive heart failure and the other two arrhythmias. Four of the five patients maintained serum ferritin levels of about 1 mg/L or below and the fifth about 1.5 mg/L for several years prior to the cardiomyopathy. Cardiac magnetic resonance imaging (MRI) T2* and T2 was performed in four patients after the cardiomyopathy, identifying the presence of moderate-to-heavy siderosis. The treatment of the five patients has since changed, involving mainly the use of L1. Low serum ferritin levels appear to be misleading for detecting cardiac iron overload and this may increase the risk of cardiomyopathy. The MRI T2 and T2* relaxation time measurements are a more accurate method of detecting cardiac iron overload. Chelation therapy using L1 or appropriate L1/DFO combinations can reduce cardiac iron overload and the mortality rate in thalassemia patients.     

Long Term Comparative Studies in Thalassemia Patients Treated with Deferoxamine or a Deferoxamine/Deferiprone Combination. Identification of Effective Chelation Therapy Protocols

For the past 2–6 years, two groups of thalassemia patients, one of 16 patients on deferoxamine (DFO) monotherapy (35–80 mg/kg, 2–5 days/week) and the other group comprising 19 patients on a deferiprone (L1) and DFO combination therapy (L1 75–100 mg/kg/day and DFO 30–60 mg/kg, 1–5 days/week), have been studied and compared before and after the introduction of the combination therapy. The patients on the combination therapy were mainly those not complying or experiencing toxicity with DFO. The effects of chelation therapy on iron load was monitored using regular serum ferritin measurements and also magnetic resonance imaging (MRI) T2* relaxation time measurements at the end of the study. In both groups, cardiac MRI T2* levels were within the normal range (>19 ms) in more than 75% of the patients. There was a substantial improvement in serum ferritin levels and normalization of the MRI T2* levels of the liver in many cases treated with the combination therapy at effective doses by comparison to the DFO group, where the serum ferritin and MRI T2* levels were largely unchanged. It would appear that the major overall determining factor in the rapid clearance of excess iron in thalassemia patients and the maintenance of normal iron stores is the selection and implementation of effective chelation dose protocols. The International Committee on Chelation (ICOC) combination protocol L1 (80–110 mg/kg/day)/DFO (40–60 mg/kg at least 3 days per week) and to a lesser extent, DFO monotherapy at about 50 mg/kg/day, 5 days/week, appears to achieve this goal.     

Uses and Limitations of Serum Ferritin,Magnetic Resonance Imaging T2 and T2* in the Diagnosis of Iron Overload and in the Ferrikinetics of Normalization of the Iron Stores in Thalassemia Using the International Committee on Chelation Deferiprone/Deferoxamine Combination Protocol

Excess cardiac iron deposition leads to congestive cardiac failure and accounts for more than 70% of deaths in thalassemia major patients. In three separate studies involving 145 thalassemia patients, serum ferritin and magnetic resonance imaging (MRI) relaxation times T2 and T2* have been compared for assessing iron load levels during chelation treatment. In two studies, variable levels of cardiac iron load have been detected by T2 and T2* in patients treated with deferoxamine (DFO), which, however, were unrelated to serum ferritin. In most cases, similar range levels from normal to severe cardiac iron load could be identified by both the T2 and T2* methods. However, in a few cases there were substantial differences in the levels detected between the two methods. In the third study, the ferrikinetics of the normalization of the iron stores during the International Committee on Chelation (ICOC) deferiprone (L1)/DFO combination protocol was followed up using T2 and T2* and serum ferritin. Iron deposits were found not to be proportionally distributed between the liver and the heart or uniformly distributed within each organ. Iron mobilization in each patient varied and iron deposits in each organ were cleared at different rates. Despite some limitations, the application of the MRI relaxation times T2 and T2* offers the best diagnostic methods for iron overload estimations in most organs and especially the heart. These MRI methods and serum ferritin could also be used for the ferrikinetics of iron mobilization and removal during chelation therapy and the normalization of the iron stores during the ICOC L1/DFO combination protocol. There is a need to standardize the two MRI relaxation times T2 and T2* methods and identify the factors causing the differences between them.     

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.     

Low serum ferritin levels are misleading for detecting cardiac iron overload and increase the risk of cardiomyopathy in thalassemia patients. The importance of cardiac iron overload monitoring using magnetic resonance imaging T2 and T2*

The incidence of cardiomyopathy was monitored in a 6-year follow-up study involving 56 transfused thalassemia patients treated with deferoxamine (DFO), deferiprone (L1) or their combination. During this period, five female patients on regular subcutaneous or intravenous DFO presented with cardiac complications. Three patients suffered congestive heart failure and the other two arrhythmias. Four of the five patients maintained serum ferritin levels of about 1 mg/L or below and the fifth about 1.5 mg/L for several years prior to the cardiomyopathy. Cardiac magnetic resonance imaging (MRI) T2* and T2 was performed in four patients after the cardiomyopathy, identifying the presence of moderate-to-heavy siderosis. The treatment of the five patients has since changed, involving mainly the use of L1. Low serum ferritin levels appear to be misleading for detecting cardiac iron overload and this may increase the risk of cardiomyopathy. The MRI T2 and T2* relaxation time measurements are a more accurate method of detecting cardiac iron overload. Chelation therapy using L1 or appropriate L1/DFO combinations can reduce cardiac iron overload and the mortality rate in thalassemia patients.     

Long term comparative studies in thalassemia patients treated with deferoxamine or a deferoxamine/deferiprone combination. Identification of effective chelation therapy protocols

For the past 2-6 years, two groups of thalassemia patients, one of 16 patients on deferoxamine (DFO) monotherapy (35-80 mg/kg, 2-5 days/week) and the other group comprising 19 patients on a deferiprone (L1) and DFO combination therapy (L1 75-100 mg/kg/day and DFO 30-60 mg/kg, 1-5 days/week), have been studied and compared before and after the introduction of the combination therapy. The patients on the combination therapy were mainly those not complying or experiencing toxicity with DFO. The effects of chelation therapy on iron load was monitored using regular serum ferritin measurements and also magnetic resonance imaging (MRI) T2* relaxation time measurements at the end of the study. In both groups, cardiac MRI T2* levels were within the normal range (>19 ms) in more than 75% of the patients. There was a substantial improvement in serum ferritin levels and normalization of the MRI T2* levels of the liver in many cases treated with the combination therapy at effective doses by comparison to the DFO group, where the serum ferritin and MRI T2* levels were largely unchanged. It would appear that the major overall determining factor in the rapid clearance of excess iron in thalassemia patients and the maintenance of normal iron stores is the selection and implementation of effective chelation dose protocols. The International Committee on Chelation (ICOC) combination protocol L1 (80-110 mg/kg/day)/DFO (40-60 mg/kg at least 3 days per week) and to a lesser extent, DFO monotherapy at about 50 mg/kg/day, 5 days/week, appears to achieve this goal.     

Effective Combination Therapy of Deferiprone and deferoxamine for the Rapid Clearance of Excess Cardiac IRON and the Prevention of Heart Disease in Thalassemia. The Protocol of the International Committee on Oral Chelators

The International Committee on Oral Chelators (ICOC) combination therapy protocol involving the administration of deferiprone (L1) during the day (80–110 mg/kg/day) and deferoxamine (DFO) (40–60 mg/kg at least 3 days/week) during the night for 8–12 hours using a pump, or the whole 24 hours using an elastomeric pump infuser, has been tested in 11 thalassemia patients (seven males, four females) over a period of 9–28 months. The patients had variable serum ferritin levels (0.54–4.6 mg/L) and cardiac iron load ranging from normal to severe siderosis levels (MRI T2*: 4.7–45 ms). There was a substantial overall reduction in serum ferritin levels (0.17–2.16 mg/L) and normalization of cardiac iron (MRI T2* >20 ms) in all patients. In two patients with severe and moderate cardiac iron load range levels, cardiac iron normalization was achieved within 9–10 months. Two patients on L1 monotherapy (80–120 mg/kg/day) maintained normal range MRI T2* cardiac iron levels over the same period. The ICOC combination therapy protocol appears to be the most effective and least cumbersome form of chelation treatment for the rapid clearance of excess iron from the heart.     

Reduction of tissue iron stores and normalization of serum ferritin during treatment with the oral iron chelator L1 in thalassemia intermedia.

In patients with thalassemia intermedia in whom hyperabsorption of iron may result in serious organ dysfunction, an orally effective iron-chelating drug would have major therapeutic advantages, especially for the many patients with thalassemia intermedia in the Third World. We report reduction in tissue iron stores and normalization of serum ferritin concentration after 9-month therapy with the oral chelator 1,2-dimethyl-3-hydroxypyrid-4-one (L1) in a 29-year-old man with thalassemia intermedia and clinically significant iron overload (SF 2,174 micrograms/L, transferrin saturation 100%; elevated AST and ALT, abnormal cardiac radionuclide angiogram) who was enrolled in the study with L1 75 mg/kg/day after he refused deferoxamine therapy. L1-Induced 24-hour urinary iron excretion during the first 6 months of therapy was (mean +/- SD, range) 53 +/- 30 (11 to 109) mg (0.77 mg/kg), declining during the last 3 months of L1 to 24 +/- 14 (13-40) mg (0.36 mg/kg), as serum ferritin decreased steadily to normal range (present value, 251 micrograms/L). Dramatic improvement in signal intensity of the liver and mild improvement in that of the heart was shown by comparison of T1-weighted spin echo magnetic resonance imaging with images obtained immediately before L1 administration was observed after 9 months of L1 therapy. Hepatic iron concentration decreased from 14.6 mg/g dry weight of liver before L1 therapy to 1.9 mg/g liver after 9 months of therapy. This constitutes the first report of normalization of serum ferritin concentration in parallel with demonstrated reduction in tissue iron stores as a result of treatment with L1. Use of L1 as a therapeutic option in patients with thalassemia intermedia and iron overload appears warranted.     

Effective combination therapy of deferiprone and deferoxamine for the rapid clearance of excess cardiac IRON and the prevention of heart disease in thalassemia. The Protocol of the International Committee on Oral Chelators

The International Committee on Oral Chelators (ICOC) combination therapy protocol involving the administration of deferiprone (L1) during the day (80-110 mg/kg/day) and deferoxamine (DFO) (40-60 mg/kg at least 3 days/week) during the night for 8-12 hours using a pump, or the whole 24 hours using an elastomeric pump infuser, has been tested in 11 thalassemia patients (seven males, four females) over a period of 9-28 months. The patients had variable serum ferritin levels (0.54-4.6 mg/L) and cardiac iron load ranging from normal to severe siderosis levels (MRI T2*: 4.7-45 ms). There was a substantial overall reduction in serum ferritin levels (0.17-2.16 mg/L) and normalization of cardiac iron (MRI T2* >20 ms) in all patients. In two patients with severe and moderate cardiac iron load range levels, cardiac iron normalization was achieved within 9-10 months. Two patients on L1 monotherapy (80-120 mg/kg/day) maintained normal range MRI T2* cardiac iron levels over the same period. The ICOC combination therapy protocol appears to be the most effective and least cumbersome form of chelation treatment for the rapid clearance of excess iron from the heart.     

Efficacy,Compliance And Toxicity Factors Are Affecting The Rate Of Normalization Of Body Iron Stores In Thalassemia Patients Using The Deferiprone And Deferoxamine Combination Therapy

The international committee on chelation (ICOC) of deferiprone (L1) and deferoxamine (DFO) combination therapy was the first protocol reported to have achieved normal range body iron store levels (NRBISL) in β-thalassemia major (β-TM) patients. A follow-up study in eight β-TM patients has been designed to investigate the factors affecting the rate of iron removal leading to NRBISL. The patients had variable serum ferritin [mean ± SE (standard error) =1692 ± 366, range 539–3845 μg/L)] and magnetic resonance imaging (MRI) T2* relaxation times cardiac (mean ± SE =11.1 ± 2.5, range 4.5–24.2 ms) and liver (mean ± SE = 4.3 ± 1.8, range 1.4–14 ms). Organ function, blood and other biochemical parameters were regularly monitored for toxicity. The ICOC L1 (80–100 mg/kg/day) and DFO (40–60 mg/kg, at least 3 days per week) combination therapy caused an increase in cardiac (mean ± SE =30.2 ± 2.3, range 22–41 ms) and liver (mean ± SE =27.6 ± 2.8, range 9.1–35 ms) T2* and reduction in serum ferritin (mean ± SE = 158 ± 49, range 40–421 μg/L) to within the NRBISL. The rate of normalization was variable and in one case was achieved within 9 months, whereas the longest was about 3 years. The initial iron load, the rate of transfusions, the combination dose protocol and the level of compliance were the major factors affecting the rate of normalization of the iron stores. No serious toxicity was observed during the study period, which lasted a total of 24.7 patient years.     

Effect of Deferiprone on Liver Iron Overload and Fibrosis in Hepatitis C Virus-Infected Thalassemia

To assess the effects of liver iron overload and fibrosis after treatment with a chelating agent in hepatitis C virus (HCV)-infected thalassemia, from April 1999 to July 2004, 45 patients with thalassemia major (age range 9–33 years, mean 19.3) received daily deferiprone (L1) for 23–60 months (75 mg/kg). The patients were divided into two groups on the basis of their hepatitis status (27 with, 18 without). Their serum was analyzed for alanine aminotransferase (GPT), aspartate aminotransferase (GOT), bilirubin (total/direct), r-glutamyl transpeptidase (r-GT), alkaline phosphatase (Alk-P), and ferritin. Liver iron overload and fibrosis were defined by a senior pathologist. No significant differences were demonstrated in serum levels of GPT, GOT, bilirubin, r-GT, Alk-P or ferritin; comparison was made for each group before and after L1 treatment. Iron scores were 2.3 ± 0.9 and 2.8 ± 0.9 for the hepatitis C negative and positive groups, respectively (p = 0.07), with liver fibrosis scores of 1.0 ± 0.5 and 0.4 ± 0.52 (p = 0.56). The two scores were not higher for the positive group. There was no evidence of: 1) greater iron overload and fibrosis in the HCV-infected thalassemic patients; 2) L1 inducing progressive hepatic fibrosis or worsening iron overload in HCV-infected thalassemic patients after long-term therapy; 3) further damage to liver cells associated with L1 treatment.     

Prevalence and Risk Factors for Cardiac and Liver Iron Overload in Adults with Thalassemia in Malaysia

We explored the severity and risk factors for cardiac and liver iron overload (IOL) in 69 thalassemia patients who underwent T2* magnetic resonance imaging (T2* MRI) in a Malaysian tertiary hospital from 2011 to 2015. Fifty-three patients (76.8%) had transfusion-dependent thalassemia (TDT) and 16 (23.2%) had non transfusion-dependent thalassemia (NTDT). Median serum ferritin prior to T2* MRI was 3848.0?μg/L (TDT) and 3971.0?μg/L (NTDT). Cardiac IOL was present in 16 (30.2%) TDT patients and two (12.5%) NTDT patients, in whom severe cardiac IOL defined as T2*?<10?ms affected six (11.3%) TDT patients. Liver IOL was present in 51 (96.2%) TDT and 16 (100%) NTDT patients, 37 (69.8%) TDT and 13 (81.3%) NTDT patients were in the most severe category (>15 mgFe/gm dry weight). Serum ferritin showed a significantly strong negative correlation with liver T2* in both TDT (rs?=?–0.507, p?=?0.001) and NTDT (r?=?–0.762, p?=?0.002) but no correlation to cardiac T2* in TDT (r?=?–0.252, p?=?0.099) as well as NTDT (r?=?–0.457, p?=?0.100). For the TDT group, regression analysis showed that cardiac IOL was more severe in males (p?=?0.022) and liver IOL was more severe in the Malay ethnic group (p?=?0.028) and those with higher serum ferritin levels (p?=?0.030). The high prevalence of IOL in our study and the poor correlation between serum ferritin and cardiac T2* underline the need to routinely screen thalassemia patients using T2* MRI to enable the early detection of cardiac IOL.     

A Practical Chelation Protocol Based on Stratification of Thalassemic Patients by Serum Ferritin and Magnetic Resonance Imaging Cardiac T2*

Our previous study showed that combined therapy with deferiprone (L1) and deferoxamine (DFO) was safe and efficacious in reducing iron overload in poorly-chelated thalassemia major patients for the short-term but the magnetic resonance imaging (MRI) T2* evaluation was not available at that time. Since October 2006, we applied a standardized chelation protocol by stratifying transfusion-dependent thalassemic patients into three groups, namely well-chelated group (A), poorly-chelated group without (B) or with (C) risk of cardiac complications, based on their serum ferritin (SF) levels and magnetic resonance imaging (MRI) cardiac T2* measurements. The patients in each group were given options of chelation regimens to improve their iron overload status. Chelation regimens included continuation or intensification of DFO alone (Regimen Ic or Ii, respectively), L1 alone (Regimen II), and combined therapy with L1 and DFO (Regimen III). Group A patients continued with Regimen Ic. Group B patients could opt for either Regimen Ii or II/III. Group C patients could opt for either Regimen Ii or III. Serum ferritin levels and MRI cardiac and liver T2* measurements were evaluated after 1 year of treatment. Fifty-seven patients (27 males, 30 females; age range 5–34 years, median: 25 years) were categorized into Group A (n = 3), B (n = 20) and C (n = 34). All Group A patients continued with DFO treatment. In Group B, seven were on Regimen Ii, five on Regimen II and five on Regimen III. In Group C, five were on Regimen Ii, two on Regimen II and 26 on Regimen III. Significant improvement was noted only for Group C patients using Regimen III (combined therapy) in SF levels, cardiac T2* and liver T2* measurements.     

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.     

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.     

Pattern of iron chelation therapy in Egyptian beta thalassemic patients: Mansoura University Children's Hospital experience

Background: The simultaneous use of deferoxamine (DFO) and deferiprone (DFP) has an additive effect in iron excretion in transfusion-dependent thalassemic patients.

Aim of the work: To evaluate the efficacy and safety of a prospective alternating therapy with DFO and DFP in patients with β-thalassemia major (TM) and increased serum ferritin with DFO monotherapy alone.

Patient and methods: Sixty patients with β-TM (mean age ± SD, 13.05 ± 6.1, range 10–20 years) with iron overload (serum ferritin > 2000 ng/ml) were studied. They received DFO at a daily dose of 40 mg/kg/day for 5–7 nights/week for the past several years. These patients were randomly assigned either to continue treatment with DFO alone (DFO group, n = 30) or prospectively receive additional alternating therapy with DFP at 75 mg/kg/day for 4 days/week and DFO for the other 2 days/week (alternating therapy group, n = 30). The efficacy of both groups was assessed by measurements of serum ferritin, echocardiography, and 24 h urine iron excretion (UIE) levels throughout 1 year follow-up.

Results: In the 60 evaluable patients, the mean serum ferritin (± SD) fell dramatically from 4500 (± 1250) ng/ml at the start of the study to 1250 (± 750) ng/ml (alternate therapy group; P < 0.001) at the end of the study. There was also a significant improvement in the myocardial function as assessed by the ejection fraction (P < 0.002) and fractional shortening (P < 0.01) in those patients on alternate therapy for 1 year. Their mean urinary iron excretion elevated from 0.41 ± 0.27 to 0.76 ± 0.49 mg/kg/24 h (P < 0.003). There was a significant difference between both groups as regard the studied parameters at the end of the study. Whereas, there was no statistical difference as regard the studied parameters at the start and the end of the study in the DFO group. No significant adverse effects had occurred in both groups that necessitated withdrawal from the study.

Conclusions: β-Thalassemic major patients with transfusional iron overload can be safely and effectively treated with an alternate therapy of DFO/DFP with a progressive fall in the mean serum ferritin and significant improvement of myocardial performance.     

Combined chelation therapy in thalassemia major with deferiprone and desferrioxamine: a retrospective study

Objectives: The benefits of combined chelation therapy with daily deferiprone (DFP) and subcutaneous desferrioxamine (DFO) have been widely reported in literature. We retrospectively evaluated the efficacy of different schedules of combined chelation therapy and the incidence of adverse events. Methods: We evaluated 36 patients affected by thalassemia major treated with combined chelation therapy. Patients were subdivided into four treatment arms according to severity of iron overload and previous onset of adverse events to DFP therapy: Group 1 (13 pts) DFP 75 mg/kg per d plus DFO (25–35 mg/kg per d for 5 d); Group 2 (6 pts) DFP 50 mg/kg per d plus DFO (25–35 mg/kg for 5 d), Group 3 (10 pts) DFP 75 mg/kg per d plus DFO (25–35 mg/kg for 3 d), and Group 4 (7 pts) DFP 50 mg/kg per d plus DFO (25–35 mg/kg for 3 d). Change in serum ferritin level was evaluated in all patients. Results: Overall, ferritin decreased from 2592 ± 1701 to 899 ± 833 ng/mL (P < 0.001). All treatments were able to reduce ferritin levels, but in patients of group 1 and group 2 the highest mean decrease in serum ferritin level and the greatest improvement in liver iron concentration (LIC) and in T2* values were observed. Conclusions: This study showed that the administration of DFO for 5 d a wk in combination with daily administration of DFP at 75 mg/Kg seemed to be the most efficacy and rapid method for reducing iron overload at liver and heart level. Furthermore, the use of different schedules of combined DFO and DFP administration was not associated with different incidence of adverse effects between the groups.     

Efficacy, compliance and toxicity factors are affecting the rate of normalization of body iron stores in thalassemia patients using the deferiprone and deferoxamine combination therapy

The international committee on chelation (ICOC) of deferiprone (L1) and deferoxamine (DFO) combination therapy was the first protocol reported to have achieved normal range body iron store levels (NRBISL) in β-thalassemia major (β-TM) patients. A follow-up study in eight β-TM patients has been designed to investigate the factors affecting the rate of iron removal leading to NRBISL. The patients had variable serum ferritin [mean ± SE (standard error) =1692 ± 366, range 539-3845 μg/L)] and magnetic resonance imaging (MRI) T2* relaxation times cardiac (mean ± SE =11.1 ± 2.5, range 4.5-24.2 ms) and liver (mean ± SE = 4.3 ± 1.8, range 1.4-14 ms). Organ function, blood and other biochemical parameters were regularly monitored for toxicity. The ICOC L1 (80-100 mg/kg/day) and DFO (40-60 mg/kg, at least 3 days per week) combination therapy caused an increase in cardiac (mean ± SE =30.2 ± 2.3, range 22-41 ms) and liver (mean ± SE =27.6 ± 2.8, range 9.1-35 ms) T2* and reduction in serum ferritin (mean ± SE = 158 ± 49, range 40-421 μg/L) to within the NRBISL. The rate of normalization was variable and in one case was achieved within 9 months, whereas the longest was about 3 years. The initial iron load, the rate of transfusions, the combination dose protocol and the level of compliance were the major factors affecting the rate of normalization of the iron stores. No serious toxicity was observed during the study period, which lasted a total of 24.7 patient years.     

Comparison of twice-daily vs once-daily deferasirox dosing in a gerbil model of iron cardiomyopathy

OBJECTIVE: Despite the availability of deferoxamine chelation therapy for more than 20 years, iron cardiomyopathy remains the leading cause of death in thalassemia major patients. Effective chelation of cardiac iron is difficult; cardiac iron stores respond more slowly to chelation therapy and require a constant gradient of labile iron species between serum and myocytes. We have previously demonstrated the efficacy of once-daily deferasirox in removing previously stored cardiac iron in the gerbil, but changes in cardiac iron were relatively modest compared with hepatic iron. We postulated that daily divided dosing, by sustaining a longer labile iron gradient from myocytes to serum, would produce better cardiac iron chelation than a comparable daily dose. METHODS: Twenty-four 8- to 10-week-old female gerbils underwent iron dextran-loading for 10 weeks, followed by a 1-week iron equilibration period. Animals were divided into three treatment groups of eight animals each and were treated with deferasirox 100 mg/kg/day as a single dose, deferasirox 100 mg/kg/day daily divided dose, or sham chelation for a total of 12 weeks. Following euthanasia, organs were harvested for quantitative iron and tissue histology. RESULTS: Hepatic and cardiac iron contents were not statistically different between the daily single-dose and daily divided-dose groups. However, the ratio of cardiac to hepatic iron content was lower in the divided-dose group (0.78% vs 1.11%, p = 0.0007). CONCLUSION: Daily divided dosing of deferasirox changes the relative cardiac and liver iron chelation profile compared with daily single dosing, trading improvements in cardiac iron elimination for less-effective hepatic chelation.