Ferritin Levels, Compliance and Adverse Events Related to Infused Iron Chelation Therapy in a Cohort of Patients from Usual Care Setting in the United States.

Blood ◽  
2006 ◽  
Vol 108 (11) ◽  
pp. 3360-3360 ◽  
Author(s):  
K.A. Payne ◽  
M.-P. Desrosiers ◽  
I. Proskorovsky ◽  
K. Ishak ◽  
N. Lordan ◽  
...  
Keyword(s):  
Adverse Events ◽  
Iron Overload ◽  
Usual Care ◽  
Care Setting ◽  
Chelation Therapy ◽  
Ferritin Level ◽  
Iron Chelation ◽  
The United States ◽  
Iron Chelation Therapy ◽  
Available N

Abstract Background: Deferoxamine (DFO) is an iron chelation therapy (ICT) agent administered to patients undergoing chronic blood transfusions to avoid toxic iron overload. Although efficacious, it is burdensome to patients due to the need for almost daily infusions lasting 8–10 hours each, and the occurrence of treatment-related adverse events (AEs). Purpose: To document ferritin levels, compliance and prevalence of AEs in a cohort of patients undergoing DFO ICT. Methods: A naturalistic cohort study of resource utilization and quality-of-life burden of infused ICT in the usual care setting (acute hospital and out-patient) was undertaken in four US treatment centers between September and December 2005. Patients aged ≥6 years with thalassemia or sickle cell disease (SCD) currently undergoing ICT were eligible to participate. This abstract refers only to patient compliance, ferritin levels and AEs related to infused ICT. Compliance (up to 7 days prior to the study) and AEs (up to 30 days prior to the study) were obtained from patient interviews. Ferritin data from these same patients during their initial and most recent year of ICT were collected from medical charts. Results: 49 patients on infused ICT (50% male; mean age: 28 ± 10 years) with thalassemia (n=40) or SCD (n=9) were recruited. Ferritin level test results obtained from charts indicate that, in general, average blood iron levels were high and remained stable or increased over time, despite ICT. During the initial year of ICT (n=35), mean ferritin level was 2687 ± 1535 ng/mL for thalassemia patients and 2088 ± 791 ng/mL for SCD patients (2519 ± 1382 overall). During the most recent year of ICT (n=45), thalassemia patients had a mean ferritin level value of 2496 ± 2556 ng/mL and SCD patients had a mean ferritin level value of 4108 ± 2030 ng/mL (2741 ± 2532 overall). For all patients in whom data from the most recent year and the initial year of ICT were available (n=29), mean ferritin level increased by 306 ± 2774 ng/mL over a mean period of 20 ± 9 years of therapy. In general, high mean ferritin level during the most recent year of ICT was associated with poor compliance reported over the previous 7-day period (Table). Seventy-seven percent of patients reported missing at least one DFO dose over the previous 4 weeks. Among these patients, 14% did so due to AEs. Over the previous 30 days, 55% suffered at least one AE; the most commonly reported were site soreness (85%), site irritation (74%), ringing in the ears (26%), temporary hearing loss (11%), blurred vision (11%) and abdominal pain (11%). Conclusions: Infused ICT may not provide adequate effectiveness in the real world. High ferritin levels seem to be associated with patient non-compliance to infused ICT, which may result from the occurrence of bothersome side effects and the burdensome mode of administration. In all patients, even those compliant, generally high ferritin levels highlight the risk for iron-overload complications. An ICT agent offering improved convenience and patient satisfaction could improve the clinical and economic outcomes of therapy. Compliance and ferritin levels associated with infused ICT Compliance (%) Patients, n (%) Mean ferritin level ± SD, ng/mL Thalassemia (n=39) 0–50 9 (23) 3615 ± 3522 51–80 14 (36) 2831 ± 2474 81+ 16 (41) 1573 ± 1694 SCD (n=6) 0–50 2 (33) 5637 ± 2850 51–80 1 (17) 3828 81+ 3 (50) 3840 ± 1965

Socio-Economic Impact of Infused Iron Chelation Therapy in France: ISOSFER Study Results.

Blood ◽  
2006 ◽  
Vol 108 (11) ◽  
pp. 3354-3354 ◽  
Author(s):  
Catherine Brun-Strang ◽  
Dora Bachir ◽  
Mariane De Montalembert ◽  
Isabelle Thuret
Keyword(s):  
Adverse Events ◽  
Chelation Therapy ◽  
Ferritin Level ◽  
Iron Chelation ◽  
Organ Damage ◽  
Total Direct Cost ◽  
Iron Chelation Therapy ◽  
Cross Sectional ◽  
Study Results ◽  
The Cost

Abstract Background: Patients suffering from β-thalassemia (TM), sickle cell disease (SCD), and myelodysplastic syndromes (MDS) undergoing chronic blood transfusions are at risk for iron overload which, if not treated by iron chelation therapy (ICT), can cause serious organ damage and reduce life expectancy. Deferoxamine (DFO) is the standard of care for the depletion of excess body iron. It has to be infused for 8–10 hours, 5–7 times a week. Although the clinical need for ICT is clearly established, less is known about the economic burden of DFO treatment. Aim: To estimate the total annual costs of DFO ICT in treatment centers in France. Methods: A cross-sectional study with a prospective recruitment. Among 278 consecutive patients receiving regular transfusions for TM, SCD or MDS who consulted between October 2005 and February 2006 in 24 French centers, 161 were on ICT. 124 patients were treated with DFO alone for more than 1 year. Among them, 67 aged 14 years or more agreed to participate. Resources used were collected through patient and physician questionnaires. Unit costs (2004/2005 €) were applied according to French economic guidelines. Results: DFO was administered via subcutaneous (sc) infusion for 70% of patients, mainly nightly and with a mean duration of 10 hours. Other ways of administering DFO included intravenous (iv) infusion (15%), sc bolus (9%) and combined sc and iv treatment (5%). Patient characteristics are summarized in the table below. TM (n=24) SCD (n=17) MDS (n=26) *Cardiac, liver and endocrine diseases, lens opacities, osteoporosis Median age (min-max), years 30 (15–70) 32 (14–57) 69 (45–85) Sex, M/F 11/13 6/11 14/12 Organ dysfunction potentially related to hemosiderosis* (%) 75 47 54 Ferritin level (median), ng/mL 1049 2653 2627 DFO nb/week (mean) 3.7 4.5 4 Dose (mean) 40 17 43 For all patients, the estimated mean weighted annual cost of infusions is 16009 € (SD ± 13867). Costs are similar for the three diseases. ICT delivery equipment (infusion set and pump) and nursing administration, drug cost, DFO adverse events monitoring, periodic exams and treatment of infused ICT-related adverse events represent respectively 56.5%, 38.5%, 0.3%, 3.7% and 0.9% of total direct cost. The estimated annual mean cost of the drug alone was 6160 € (SD ± 4145). Average cost for DFO adverse events management is low at 151.5€ (SD ± 1224), essentially due to one patient complication. Costs of periodic exams are also low due to the fact that exams are not strictly performed annually as recommended. These estimates of the total annual costs of DFO ICT are likely to be underestimating the overall cost of DFO therapy because treatment costs of the clinical consequences of poor adherence to DFO and lost productivity were not collected in the study. Conclusions: ISOSFER demonstrated that total direct costs of ICT are substantial and well exceed the cost of DFO alone. The cost of DFO administration constitutes a significant portion of the total cost of iron chelation (54%). These data are comparable to other analyses published from US (43% of the total costs, n=155) and Swiss (45%, n=17) databases.

Iron Overload and Haematopoiesis in MDS: Does Blood Transfusion Promote Progression to AML?

Blood ◽  
2008 ◽  
Vol 112 (11) ◽  
pp. 2685-2685 ◽  
Author(s):  
Lap Shu Alan Chan ◽  
Rena Buckstein ◽  
Marciano D. Reis ◽  
Alden Chesney ◽  
Adam Lam ◽  
...  
Keyword(s):  
Bone Marrow ◽  
Dna Damage ◽  
Iron Overload ◽  
Serum Ferritin ◽  
Chelation Therapy ◽  
Bone Marrow Cells ◽  
Ferritin Level ◽  
Iron Chelation ◽  
Iron Chelation Therapy ◽  
Ferritin Concentration

Abstract Introduction: The biology of myelodysplastic syndrome (MDS) is poorly understood, and treatment options are limited. Thus, most MDS patients require chronic red blood cell transfusion, and many develop secondary iron overload. Although the pathophysiological consequences of iron overload to the heart, liver, and endocrine organs have been well characterized, its effects on haematopoiesis have not been studied. However, it has been observed that chelation therapy in iron-overloaded MDS patients may result in reduction of transfusion requirements, and recent studies have suggested a correlation between the use of iron chelation therapy and improvement in leukaemia-free survival in MDS. At the cellular level, iron toxicity is mediated in large part via the generation of reactive oxygen species (ROS). It has been shown in animal models that accumulation of ROS leads to senescence of haematopoietic stem cells, and that ROS cause DNA damage and promote the development of malignancy. These effects of ROS may be particularly important in MDS, in which haematopoiesis is already severely compromised and genetic instability is a striking feature. Hypothesis: We hypothesize that iron overload secondary to transfusion leads to increased levels of intracellular ROS in early haematopoeitic cells in MDS. The increase in intracellular ROS in MDS would be predicted to lead further impairment of haematopoiesis via stem cell exhaustion and while promoting accumulation of DNA damage by myelodysplastic stem cells and early progenitors, thus accelerating progression of MDS to acute leukaemia. Results: To test this hypothesis, we examined the relationship between transfusion-related iron overload and ROS content of CD34+ bone marrow cells in MDS. ROS content was measured in CD34+ cells by flow cytometry in bone marrow aspirates from 34 consecutive MDS patients (CMML=4, MDS/MPD=2, RA=4, RARS=3, RCMD=2, RAEB 1=6, RAEB 2=12, RAEB-t/AML=1). The patients represented a wide range of prior transfusion burden (0->300 units PRBC) and serum ferritin levels (11->10000 μg/L). ROS was strongly correlated with serum ferritin concentration for patients with iron overload (serum ferritin >1000 μg/L; n=14, R=0.733, p<0.005). The correlation between ROS and ferritin level was even stronger in the subset of patients with RAEB 1 or RAEB 2 and iron overload (n=11, R=0.838, p<0.005). In contrast, no correlation between ROS and ferritin level was demonstrated for patients with serum ferritin <1000 μg/L (n=20). Importantly, iron chelation therapy was associated with a reduction in CD34+ cell ROS content in one patient. To assess the effect of iron overload on normal stem cell and progenitor function, we established a mouse model of subacute bone marrow iron overload. B6D2F1 mice were loaded with iron dextran by intraperitoneal injection (150mg total iron load over 21 days), and sacrificed three days after the end of iron loading. Iron staining of tissue sections confirmed iron deposition in the bone marrow, liver, and myocardium. The development of splenomegaly was noted in iron-loaded animals. Flow cytometric analysis revealed increased apoptosis of bone marrow cells in iron loaded mice based on annexin V+/7 AAD-staining (6.26±0.96% versus 3.54±0.99% for control mice, paired student’s t-Test p<0.005). However, ROS content in CD117+ progenitors of iron loaded mice was similar to control mice. Thus, subacute iron loading in mice increases apoptosis but does not alter the ROS content of HSCs; we postulate that chronic iron overload is required to achieve this effect. Conclusions: These results establish a relationship between CD34+ cell ROS content and serum ferritin concentration in MDS patients with iron overload, and indicate that iron chelation therapy in this patient population reverses this ROS accumulation. The physiological consequences of this relationship are currently being investigated in this patient set by haematopoietic colony assays and assessment of DNA damage in CD34+ cells. Nonethelesss, these data may have key implications for the deployment of iron chelation therapy in MDS patients, and may explain the association between the use of iron chelation and improved leukaemia-free survival in MDS.

Are Children with Cancer Receiving Myelosuppressive Therapy At Risk for Transfusion-Related Iron Overload?

Blood ◽  
2012 ◽  
Vol 120 (21) ◽  
pp. 1180-1180
Author(s):  
Anushka Jaffer ◽  
Rebecca Barty ◽  
Erin Jamula ◽  
Grace Wang ◽  
Yang Liu ◽  
...  
Keyword(s):  
At Risk ◽  
Iron Overload ◽  
Chelation Therapy ◽  
Ferritin Level ◽  
Iron Chelation ◽  
Iron Chelation Therapy ◽  
Children With Cancer ◽  
Screening Practices ◽  
The Impact ◽  
Rbc Transfusion

Abstract Abstract 1180 Background Transfusion-related iron overload (TRIO) is associated with significant morbidity and mortality. Adequate screening for iron overload (IO) and the use of iron chelators, if needed, should be employed for chronically transfused individuals. However, with the exception of patients with hemoglobinopathies, screening for iron overload is not a consistent part of routine care for patients receiving multiple red cell transfusions, and is not identified as a treatable problem. Objective This study aimed to identify the population at risk for TRIO and to evaluate current screening practices. Methods All children (≤ 18 years) receiving at least one red blood cell (RBC) transfusion between January 1, 2008 and December 31, 2011 at our institution were identified using the TRUST (Transfusion Registry for Utilization, Surveillance and Tracking) database. Only patients receiving chronic RBC transfusion were included in this study, which was defined as receiving ≥20 units of RBC or ≥ 20 RBC transfusions dosed at 15ml/kg within 12 consecutive months where the transfusions were not administered in the setting of an operating room, trauma or surgical procedure(s), not administered 7 days prior/post-surgical procedures and not all administered within one day. Adjudication by a second reviewer resolved any ambiguity regarding study inclusion. Medical records of eligible patients were reviewed to collect patient demographics, underlying diagnosis and reason for transfusions, and to evaluate IO screening practices (e.g. ferritin level, testing for systemic IO (e.g. FerriScan) if persistently high ferritin) and frequency of iron chelation therapy. Results A total of 35 patients fulfilled the eligibility criteria, with a mean age of 8.82 years (SD 5.36). Table 1 summarizes the demographics of the population, the transfusion requirements, how often the patient subgroups were screened and the screening results. In summary, 20 patients had ferritin levels checked, where 2 (AML and hepatoblastoma) patients had values under 500 μg and no screening was required. Of the remaining 18, 10 patients were diagnosed with a hemoglobinopathy (8) and congenital anemia (2) requiring chronic transfusions and underwent regular screening for iron overload and received iron chelation therapy. The remaining 8 patients had ferritin level >500 μg but no IO screening ordered. Of these 8 patients the majority were diagnosed with a cancer (leukemia, solid tumours) (5), acquired aplastic anemia (2), and hemophagocytic syndrome (1). The total number of transfusions for these 8 patients ranged from 20 to 52 with a median of 25 transfusions. Conclusion The majority (63%) of chronically transfused patients in this cohort had underlying cancer requiring aggressive chemotherapy. Only 32% of these patients had ferritin level tested and none were evaluated for systemic IO. TRIO may represent an additional, as yet unidentified, co-morbidity of cancer therapy. Therapies such as anthracycline or radiation may potentiate the end organ effect of TRIO at levels lower than that observed in patients with a hemoglobinopathy. Hence, it is important to develop strategies to evaluate children with cancer at risk for IO and to study the impact of transfusional iron accumulation on end organ function. Disclosures: No relevant conflicts of interest to declare.

Multidisciplinary Evaluation Improves Efficacy and Safety of Iron Chelation Therapy with Deferasirox in MDS Elderly Patients

Blood ◽  
2015 ◽  
Vol 126 (23) ◽  
pp. 4558-4558
Author(s):  
Lisette Del Corso ◽  
Elisa Molinari ◽  
Andrea Bellodi ◽  
Riccardo Ghio ◽  
Andrea Bacigalupo ◽  
...  
Keyword(s):  
Serum Creatinine ◽  
Iron Overload ◽  
Serum Ferritin ◽  
Serum Ferritin Level ◽  
Chelation Therapy ◽  
Ferritin Level ◽  
Iron Chelation ◽  
Iron Chelation Therapy ◽  
Group A ◽  
Group B

Abstract BACKGROUND: Iron overload from chronic transfusion therapy can be extremely toxic and most patients (pts) do not receive adequate iron chelation therapy (ICT) despite evidence of transfusional iron overload (IOL). Deferasirox (DFX) is the principal option currently available for ICT in the management of IOL due to transfusion dependent anemia, such as in MDS pts. The most common adverse events (AEs) are gastrointestinal disorders, skin rash, elevations in liver enzymes levels and non-progressive transient increases in serum creatinine also in MDS pts, most of whom are elderly with significant comorbidities and side effects of other concomitant therapies. In order to achieve effective ICT with minimal toxicity in individual pts, regular monitoring to assess IOL and adverse effects of DFX treatment is essential. METHODS: The safety and efficacy of DFX were examined in a retrospective multicenter observational study of transfusion-dependent (TD) MDS pts with International Prognostic Scoring System (IPSS) low-or Int-1-risk. We included all pts treated with DFX up to 12 months, divided into two groups; the first one (group A) not under a multidisciplinary assessment, including pts not adequately treated, in terms of dosing and discontinuation of ICT and the second one (group B) with pts under multidisciplinary control. The DFX starting dosing was 10 mg/kg/die in all pts. The aim of our retrospective analysis was to assess the effectiveness of ICT in relation of dosing and right management of AEs. RESULT: We evaluated 45 MDS pts (12F/33M); 27 belonging to the group A and 18 to group B. The age was 74.2±8.8 and 77.3±4.8 respectively. The ECOG 0-1 was 85,1% in group A and 88,9% in group B. The transfusion episodes prior starting DFX were22.1±12.1 and 24.5±35.4 in the first and in the second group, respectively. The serum ferritin level at baseline was respectively 1285.1±489.6 ng/mL and 1452.6±748.1 ng/mL. The mean serum ferritin level increased from 1285.1+489.6 ng/mL to 1412.1+842.8 ng/mL in group A while decreased from 1452.6+748.1 ng/mL to 1166.1+ 723.4 ng/mL in group B. The rate of inadequate therapy, in terms of dosing and/or discontinuation ICT, was 85% in group A compared to 60% in group B (p= 0.086).The rate of severe SAE observed in all pts was 10%.The most common AEs were diarrhea, nausea, upper abdominal pain, serum creatinine increase. The positive hematological response rate was observed in 15% of all pts. CONCLUSIONS: The study showed that group B obtained advantage in terms of efficacy and toxicity. The difference between the two groups derived from the ability to manage comorbidities, concomitant therapies and AEs, in particular the rise in serum creatinine, the most common cause DFX discontinuation or dosing reduction. In this setting, the most important specialist was the nephrologist. In our multidisciplinary group experts in management of ICT were hematologist, internist, immune-hematologist and nephrologist. We shared how we monitored kidney function and managed a possible nephrotoxicity (table.2), in order to ensure DFX efficacy. Positive hematological responses were observed, and a subset of pts achieved transfusion independence. The timing of future multidisciplinary evaluation is set on 24 and 36 months, time in which we expect the best response to DFX therapy. Table 1. Ferritin trend group A (n27) group B (n18) Ferritin N mean±SD Median (range) N mean±SD Median (range) Baseline 27 1285.1±489.6 1134 (388-2099) 18 1452.6±748.1 1515 (160-3018) 3 months 22 1451.5±720.5 1247.5 (529-2791) 13 1312.7±909.8 1064 (521-3859) 6 months 23 1850.5±1079.1 1419 (374-4185) 11 1168.4±648.4 1300 (160-2409) 12 months 17 1412.1±842.8 1372 (111-3127) 9 1166.1±723.4 930 (277-2536) Table 2. Management of renal changes during therapy with DFX Creatinine and urine examination:1) in two successive determinations prior to initiation of therapy, then every month 2) in pts with other risk factors for kidney disease, every week for 1 month after start of DFX or dose increase and, subsequently, every month Changes in creatinine:1) increased by 33% in two successive determinations: reduce DFX dose of 5 mg/kg 2) progressive increase of creatinine: interrupt DFX and then re-challenge it at a lower dose with gradual increase if the clinical benefits outweigh the risks Disclosures No relevant conflicts of interest to declare.

Improved Survival in Patients with Myelodysplastic Syndrome (MDS) Receiving Iron Chelation Therapy.

Blood ◽  
2006 ◽  
Vol 108 (11) ◽  
pp. 249-249 ◽  
Author(s):  
Heather A. Leitch ◽  
Trisha A. Goodman ◽  
Karen K. Wong ◽  
Linda M. Vickars ◽  
Paul F. Galbraith ◽  
...  
Keyword(s):  
Clinical Outcome ◽  
Iron Overload ◽  
Causes Of Death ◽  
Clinical Evidence ◽  
Chelation Therapy ◽  
Ferritin Level ◽  
Iron Chelation ◽  
Low Risk ◽  
Iron Chelation Therapy

Abstract Patients (pts) with MDS and iron overload often receive iron chelation therapy (ICT), although there are no data demonstrating that this improves clinical outcome. Pts with thalassemia receiving ICT do have improved survival and a decrease in number of end-organ toxicities. We performed a retrospective review of 178 pts seen at St.Paul’s Hospital in Vancouver, Canada, from January 1981 to April 2006, with a bone marrow diagnosis (Dx) of MDS. Clinical data were collected from the practice database, the Iron Chelation Program of British Columbia database, and by chart review. Pts receiving ICT were treated with desferroxamine 0.5–3g by subcutaneous infusion over 12 hours, 5 days per week. 105 were male and 73 female. MDS Dx were: RA, n=36; RARS, n=42; RAEB, n=28; RAEB-t or AML, n=16, CMMoL, n=25; other, n=31. Age at Dx was a median of 69 (18–94) years. Median absolute neutrophil count (ANC) was 1.6 (33–155) G/l, hemoglobin (Hgb) 96.5 (33–155) G/l, and platelet count 115 (7–644) G/l. Cytogenetic analysis was available in 128 pts; low risk (as defined by the IPSS), n=85; intermediate, n=22; high, n=21. Calculation of IPSS score was feasible in 133 pts; low risk, n=44; int-1, n=55; int-2, n=17; high, n=17. An elevated ferritin level, defined as a serum ferritin of ≥ 2000 ug/ml, was found in 28 pts. Clinical evidence of iron overload was present in 22 pts; CHF with no other contributing factor n=5; liver disease n=18; endocrine dysfunction, n=4; other, n=4; biopsy or imaging evidence was available in 6 pts. Of 18 pts receiving ICT, median duration of ICT was 15 (0–37) months (mo) and reasons for initiating ICT were: elevated ferritin, n=13; clinical and biochemical evidence of iron overload, n=3; number of transfusions received, n=2. In ICT pts, median ferritin level pre-ICT was 4215 (1500–8400) and post-ICT was 2659 (567–5228). In non-ICT pts with elevated ferritin, median ferritin after Dx was 1647 (265–5009) ug/L and at recent follow up was 3188 (763–12723) ug/L. There was a trend toward higher initial ferritin level in ICT pts (p<0.07) and significantly lower post-ICT ferritin in ICT pts compared to follow up ferritin in non-ICT pts (p<0.003). Documented causes of death in non-ICT pts were AML, n=22; MDS-related, n= 21; infection/sepsis, n=18 and non-MDS related, n=10. Documented causes of death in ICT pts were AML, n=1; MDS related, n=1; iron overload, n=1. Kaplan-Meier analysis showed that median overall survival (OS) for all pts was 36 (0.7–255.9) mo. Age showed a trend toward significance for OS (p<0.1); other factors that were significant included IPSS score, (p<0.0001); Dx, (p<0.0001); number of red blood cell units transfused, (p<0.0001); occurrence of ≥1 serious infectious episode, (p< 0.002); AML transformation, (p<0.0001); MDS-directed treatment, (p<0.04); elevated ferritin, (p<0.004); clinical evidence of iron overload, (p<0.001); and ICT, (p<0.001). In Cox regression analysis, the only factors significant for OS were IPSS score (p<0.008) and ICT (p<0.02). For pts with low or int-1 IPSS, median OS for pts receiving ICT was not reached at 160 mo vs. 40.1 (0.7–224) mo for non-ICT pts (p<0.03). In conclusion, although we were not able to demonstrate a decrease in organ dysfunction in pts receiving ICT for MDS, there was a significant improvement in OS. These are to our knowledge the first data documenting improvement in clinical outcome in pts with MDS receiving ICT.

scholarly journals A Randomized Trial on the Safety and Efficacy of Early Start of Iron Chelation Therapy with Deferiprone in Newly Diagnosed Children with Transfusion Dependent Thalassemia

Blood ◽  
2016 ◽  
Vol 128 (22) ◽  
pp. 1286-1286
Author(s):  
Mohsen Saleh Elalfy ◽  
Vasilios Berdoukas ◽  
Fernando Tricta ◽  
Amira Adly ◽  
Nyeria Hazza ◽  
...  
Keyword(s):  
Adverse Events ◽  
Iron Overload ◽  
Chelation Therapy ◽  
Transferrin Saturation ◽  
Iron Chelation ◽  
Iron Accumulation ◽  
Iron Chelation Therapy ◽  
Newly Diagnosed ◽  
Abdominal Colic

Abstract Iron toxicity is the main risk factor for morbidity and mortality in patients with transfusion-dependent thalassemia. Current practice is to start chelation therapy only after 10-20 transfusions, or when the serum ferritin (SF) level rises above 1,000 μg/L. This delay is aimed at minimizing the risk of chelation toxicity that was observed with the use of deferoxamine in children with low iron stores. Deferiprone has lower affinity for iron than deferoxamine and data from clinical trials on its use in patients without systemic iron overload indicate a safety profile for its use in those conditions. The current trial was designed to evaluate the safety of the early use of low-dose deferiprone in newly diagnosed pediatric thalassemia and to evaluate if it can postpone iron overload. Sixty-four children recently diagnosed with thalassemia major who had begun receiving blood transfusions every 3-4 weeks to keep pre-transfusion Hb above 10 gm/dl, had not yet started iron chelation therapy and had SF ≥ 400 μg/L or transferrin saturation (TSAT) ≥ 70% or labile plasma iron (LPI) ≥ 0.2 µM were randomized to start deferiprone (DFP) at a dose normally considered to be sub-therapeutic (50 mg/kg/day) or no chelation (NC). Age at 1st transfusion was 8.1 ± 1.7 for DFP-treated and 8.1 ± 1.6 months for NC children. The percentage of patients with LPI ≥ 0.6 µM, SF ≥ 1000 μg/L or TSAT ≥ 70% in each study arm was assessed at 6 months and 12 months. Patients with confirmed SF ≥1000 ng/mL were withdrawn from the study and placed on a standard chelation regimen. Results. Two patients (DFP) were lost to follow after baseline measurements, 1 patient (NC) withdrew consent at baseline, and 10 patients (5 DFP, 5 NC) have yet to complete all follow up visits. All NC patients had been removed from the trial prior to completing 7 months of follow-up 12 due to confirmed SF ≥ 1000 μg/L. Mean ± SD time of follow up was 10.4± 4.9 and 5.9 ± 2.5 months for DFP and NC, respectively. Most common adverse events in patients on DFP versus NC were diarrhoea (19% vs 13%, p= 0.73), vomiting (13% vs 13%, p=1.00), abdominal colic (13% vs 13%), increased liver enzymes (6% vs 3%, p=1.00) and neutropenia (neutrophil count between 1,000-1,500 x 109/L) (6% vs 6%). All adverse events were mild in severity and did not require interruption of DFP use. There were no cases of agranulocytosis or of moderate neutropenia, no arthralgia and no serious infections in DFP-treated patients. Preliminary efficacy results are presented in the table. DFP therapy was associated with a significant reduction in the rate of iron accumulation as measured by SF (P<0.0001) (Figure 1), LPI (P<0.001) (Figure 2) and TSAT (P<0.001). LPI ≥ 0.6 µM appeared as early as after 5 transfusions in NC children and was delayed to at least 10 transfusions with DFP therapy. TSAT ≥ 70% appeared after 10 transfusions in NC children and was delayed to at least 17 transfusions with DFP therapy. The results of this study show that LPI and TSAT may reach values ≥ 0.6 µM and ≥ 70%, respectively, after 5 -10 transfusions in children with TM and all NC children had SF ≥ 1000 μg/L after 8-9 transfusions. A sub-therapeutic dose regimen of deferiprone for a mean of 10 months in children with TM and low iron overload was not associated with safety concerns and able to significantly reduce the rate of iron accumulation as measured by SF and the appearance of high levels of LPI and of TSAT. Table Table. Disclosures Berdoukas: ApoPharma Inc: Consultancy. Tricta:ApoPharma Inc: Employment.

Matched-Pair Analysis of 186 MDS Patients Receiving Iron Chelation Therapy or Transfusion Therapy Only.

Blood ◽  
2009 ◽  
Vol 114 (22) ◽  
pp. 1747-1747 ◽  
Author(s):  
Frank Fox ◽  
Andrea Kündgen ◽  
Kathrin Nachtkamp ◽  
Corinna Strupp ◽  
Rainer Haas ◽  
...  
Keyword(s):  
Iron Overload ◽  
Chelation Therapy ◽  
Ferritin Level ◽  
Iron Chelation ◽  
Matched Pair ◽  
Iron Chelation Therapy ◽  
Transfusion Therapy ◽  
Matched Pair Analysis ◽  
Advisory Boards ◽  
Pair Analysis

Abstract Abstract 1747 Poster Board I-773 Introduction Patients with MDS, especially those with a lower-risk type of disease, are prone to develop iron overload, partly due to increased duodenal iron resorption triggered by ineffective erythropoiesis, but mainly as a consequence of chronic transfusion therapy. Transfusion dependency is clearly associated with a decreased likelyhood of survival. It is less clear how far that association is attributable to the severity of the underlying bone marrow disease as opposed to toxic effects of iron overload. A large retrospective study from Spain recently showed that iron overload (serum ferritin >1000 ng/μl) was a significant prognostic factor for overall survival and leukemia-free survival. On multivariate analysis, the impact of iron overload was independent of transfusion requirement. If iron overload itself has an adverse effect on survival, iron chelation (IC) should do the opposite. This was indeed suggested by a partly retrospective and partly prospective observational study from France which showed a strong survival benefit from chelation therapy in patients with lower-risk MDS. We gathered that short of a prospective phase III trial, a retrospective matched-pair analysis might provide the best available data to identify a survival effect of iron chelation therapy in MDS. Methods Our matched-pair analysis included 93 patients with various types of MDS undergoing long-term chelation therapy, for whom we were able to identify 93 matched partners in the Düsseldorf MDS Registry (n=3552) who received supportive care only (SC, excluding iron chelation). Pairs were matched according to age at diagnosis, gender, MDS type according to WHO classification, and IPSS score. All 186 patients had iron overload, defined as serum ferritin of at least 500ng μl. Patients were followed up until death or until June 30, 2009. Results Median age was 63 yrs in the iron chelation group and 67 yrs in the supportive care group (p=n.s.). In both groups, the distribution among WHO types was as follows: 4 RA, 7 RARS, 41 RCMD, 22 MDS with del(5q), 8 RAEB I, 7 RAEB-II, 4 CMML-I. Both groups showed the following IPSS risk profile distribution: 37% low risk, 46% intermediate-I, 14% intermediate-II, and 3% high risk. Median ferritin level in the chlelated group was 1954 (498-7580), median ferritin level in the non-chelated group was 945 (508-5800). In the IC group, patients received the following chelators: deferoxamine (n=54), deferiprone (n=5), deferasirox (n=32), deferoxamine or followed by deferasirox (n=12), and deferoxamine plus deferiprone (n=4). The mean duration of the iron chelation was 28 months for Deferasirox and 39 months for Deferoxamine. Among patients receiving iron chelation therapy, 52% died in the observation period, as compared with 58% in the SC group. Median survival time in the IC group was 74 months vs. 49 months in the SC group (p=0.002). There was no significant difference regarding the risk of evolution into acute myeloid leukemia (AML). The cumulative risk of AML transformation between the IC group and the SC group was 10% vs. 12% two years after diagnosis, and 19% vs. 18% five years after diagnosis (p=0.73). Conclusions Our data support the idea that iron chelation therapy results in improved overall survival of MDS patients, mainly by reducing the risk of non-leukemic death. Since this was a retrospective analysis of registry data, we cannot determine exactly which clinical complications (e.g. cardiac events or infections) were diminished. This goal must be achieved by a well-designed prospective clinical trial. Our results do not seem to confirm that iron chelation therapy decreases the risk of leukemic transformation. However, such an effect may require elimination of labile plasma iron in order to suppress oxidative stress. LPI levels were not available in this retrospective matched-pair analysis but should be included in prospective studies. Disclosures Fox: Novartis: Consultancy, Honoraria, Participation in advisory boards in desferasirox trials, Speakers Bureau. Germing:Novartis: Honoraria, Research Funding, Speakers Bureau. Gattermann:Novartis: Honoraria, Participation in Advisory Boards on deferasirox clinical trials.

Improved Survival with Iron Chelation Therapy for Lower IPSS Risk MDS Appears to Have a Stronger Association in Patients with a Non-RARS Diagnosis

Blood ◽  
2011 ◽  
Vol 118 (21) ◽  
pp. 1732-1732
Author(s):  
Heather A Leitch ◽  
Christopher Chan ◽  
Chantal S Leger ◽  
Lynda M Foltz ◽  
Khaled M Ramadan ◽  
...  
Keyword(s):  
Iron Overload ◽  
Board Of Directors ◽  
Lower Risk ◽  
Research Funding ◽  
Chelation Therapy ◽  
Ferritin Level ◽  
Iron Chelation ◽  
Iron Chelation Therapy ◽  
Advisory Committees

Abstract Abstract 1732 Background: Several retrospective analyses suggest that transfusional iron overload portends inferior survival in lower risk MDS and that iron chelation therapy (ICT) is associated with improved survival in this group of patients. However an analysis of 126 patients with RARS from the Mayo Clinic showed no association between elevated ferritin level at diagnosis or transfusion burden on overall survival (OS). We performed a retrospective analysis of 268 MDS patients seen at our center to determine whether an association between transfusional iron overload or receiving iron chelation therapy (ICT) and survival differed between RARS and other lower risk MDS. Methods: Patients were identified from the clinical database of the hematology practice. Patients with a diagnosis (dx) of MDS confirmed by bone marrow biopsy (bmbx) were included. Clinical and laboratory data were collected by retrospective chart review. Survival analyses were performed using SPSS version 19. Results: 268 patients with a bmbx confirmed diagnosis of MDS by WHO or FAB criteria were identified. The following patients were excluded: uncertain IPSS score, n=35; intermediate-2 risk, n=33; high risk, n=16; RAEB-t, n=3; concomitant diagnosis of advanced stage non-Hodgkin lymphoma of uncertain type, n=1. The remaining 182 patients had the following characteristics: median age 69.5 (range 30–94) years and 109 (69.9%) were male. Specific MDS dx were: RA, n=27; RARS, n=53; RCMD, n=34; RAEB, n=15; MDS-U, n=22; hypocellular MDS, n=6; 5Q- syndrome, n=6; CMML, n=21. IPSS scores for all patients were: intermediate-1, n=101; low, n=74; uncertain (but IPSS score not >1.0), n=7. The marrow blast count was 6–9 x109/L in 4 patients and <5 x109/L in all others. Specific MDS treatment (rx) was: supportive care, n=82; erythropoiesis stimulating agents (ESA), n=22; immunosuppressive therapy (IST), n=10; lenalidomide, n=7; and chemotherapy, n=6. 137 patients received RBC transfusions and 38 received ICT: deferasirox (DFX), n=19; deferoxamine (DFO), n=9; DFO followed by DFX, n=9; and DFX followed by DFO, n=1. The median duration of ICT was 10.5 (range 0.5–64) months. Clinical features significantly associated with OS in univariate analyses of all 182 patients included: specific MDS dx; IPSS score; total number of red blood cell (RBC) units transfused over the course of follow-up; receiving ICT; specific MDS rx received; requirement for hospitalization; experiencing at least one episode of infection; and AML transformation (P</=0.01 for all); serum ferritin level >1000ng/mL was not significant in this analysis (P=not significant [NS]). In a multivariate analysis (MVA), the following factors remained significant for OS: specific MDS dx; IPSS score; receiving ICT; specific MDS rx; and AML transformation (P</=0.01 for all). In an MVA stratified for RARS, significant were: specific MDS dx (P<0.0001); IPSS score (P=0.005); specific MDS rx (P=0.038) and receiving ICT (P=0.039). At a median follow-up of 28 (0.1–245.9) months, 121 patients were alive (non-RARS, n=83 [64.3%]; RARS, n=38 [71.6%]) and the projected median OS for all patient was 99 months. The projected median OS for non-RARS patients without ICT and with ICT was 44 months and not reached (NR), respectively, and for RARS without and with ICT was 99 and 134.4 months (P<0.0001). The 5 year OS in these four groups was 39.2% and 91.7% (P=0.04); and 72.4% and 76.3%, respectively (P=NS). However, when RARS ICT patients were compared to only RBC transfusion dependent RARS patients not receiving ICT, the median OS was 73.8 vs 134.4 months, respectively, and 5 year OS was 59.9% and 76.3%, respectively (P=0.025). Conclusions: These results suggest an association between receiving iron chelation therapy and survival in lower IPSS risk MDS, in keeping with prior analyses. However, the association between ICT and OS in non-RARS MDS appeared to be stronger than in RARS, in keeping with data from Mayo suggesting transfusional iron overload may not have a major association with outcome in RARS. The median follow-up in the current study was just over 2 years, and median duration of ICT only 10.5 months; longer follow-up may be needed in RARS to determine whether ICT is potentially beneficial in this subgroup of patients with a relatively long expected survival. As with all retrospective analyses, these results must be considered hypothesis generating, and prospective trials are needed for firm conclusions to be drawn. Disclosures: Leitch: Novartis Corporation: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding, Speakers Bureau. Off Label Use: Iron chelation agents for the treatment of transfusional iron overload in MDS. Vickars:Novartis Corporation: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding.

Natural Course Of Serum Ferritin In Childhood Cancer Survivors: Need For Iron Removal Therapy?

Blood ◽  
2013 ◽  
Vol 122 (21) ◽  
pp. 2394-2394 ◽  
Author(s):  
Hideaki Maeba ◽  
Rie Kuroda ◽  
Toshihiro Fujiki ◽  
Shintaro Mase ◽  
Raita Araki ◽  
...  
Keyword(s):  
Iron Overload ◽  
Cancer Survivors ◽  
Childhood Cancer ◽  
Serum Ferritin ◽  
Serum Ferritin Level ◽  
Chelation Therapy ◽  
Ferritin Level ◽  
Iron Chelation ◽  
Childhood Cancer Survivors ◽  
Iron Chelation Therapy

Abstract Background Iron overload has been reported in adult survivors of leukemia after chemotherapy with or without allogeneic hematopoietic stem cell transplantation (allo-HSCT). Approximately 10-15% of adult survivors suffer from liver dysfunction, endocrine disorders, and/or cardiac dysfunction due to iron overload, in which free radicals produced by iron could damage tissues. Therefore phlebotomy and iron chelation therapy in adult survivors have been used prophylactically, however iron overload has not been studied extensively in childhood survivors, so that it would be a problem how to manage the childhood patients in whom serum ferritin level was high at the completion of chemotherapy. In this study, we retrospectively analyzed the serum ferritin level over time after the completion of therapy and also referred to whether iron chelation therapy and/or phlebotomy would be needed or not in childhood survivors. Patients and methods We retrospectively analyzed the level of serum ferritin overtime in 48 childhood cancer survivors (ALL 19, AML 13, Lymphoma 5, Pediatric solid tumor 11) except allo-HSCT, who were transfused concentrated red cells in our hospital. All the patients did not receive any phlebotomy and iron chelation therapy throughout the course. Results The total mean concentrated blood transfusion volume was 114 ml/kg (114±16, ranges 7-672). At the completion of chemotherapy, the median serum ferritin level was 867 ng/ml (867±216, ranges 7-6558). Three years after chemotherapy, the median serum ferritin levels decreased to 281 ng/ml (281±77, ranges 7-1285). All patients did not show any symptoms related to iron overload such as liver dysfunction and glucose intolerance. Twelve out of 48 patients (25%) exceeded 1000 ng/ml of the serum ferritin at the time of completion of chemotherapy, which has been considered as the initiation of iron chelation therapy in adult patients. However all patients except one decreased the serum ferritin level below 1000 ng/ml in 3 years after chemotherapy without any iron removal therapy. Although serum ferritin level in the exceptional case was extraordinary high (6558 ng/ml) compared to other cases at the completion of chemotherapy, it declined to 1285 ng/ml spontaneously in 3 years, which was much better than expected. Conclusions Although 25 percent of our childhood cancer survivors showed high level of serum ferritin more than 1000 ng/ml at the time of completion of chemotherapy, almost all the cases eventually declined thereafter without any iron removal therapy probably due to the iron consumption with growth. Further study would be needed to make specialized criteria for initiating iron removal therapy for childhood cancer survivors. Disclosures: No relevant conflicts of interest to declare.

Iron Chelation Therapy in CAPD: A New and Effective Treatment of Iron Overload Disease in Esrd Patients

1983 ◽  
Vol 3 (2) ◽  
pp. 99-101 ◽  
Author(s):  
Glen H Stanbaugh ◽  
A. W, Holmes Diane Gillit ◽  
George W. Reichel ◽  
Mark Stranz
Keyword(s):  
Peritoneal Dialysis ◽  
Iron Overload ◽  
End Stage Renal Disease ◽  
Chelation Therapy ◽  
Iron Chelation ◽  
Iron Chelation Therapy ◽  
Peritoneal Dialysate ◽  
Stage Renal Disease ◽  
End Stage ◽  
Esrd Patients

A patient with end-stage renal disease on CAPD, and with massive iron overload is reported. This patient had evidence of myocardial and hepatic damage probably as a result of iron overload. Treatment with desferoxamine resulted in removal of iron in the peritoneal dialysate. On the basis of preliminary studies in this patient it would appear that removal of iron by peritoneal dialysis in conjunction with chelation therapy is safe and effective. This finding should have wide-ranging signficance for patients with ESRD.

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