Reduction of Hepatic Iron in Patients with Thalassemia Major According to Iron Chelation Regime Assessed by MRI T2*

Blood ◽  
2008 ◽  
Vol 112 (11) ◽  
pp. 5410-5410
Author(s):  
Vassilios Ladis ◽  
Giorgos Chouliaras ◽  
Kirikos Zannikos ◽  
Panagiotis Moraitis ◽  
Eleni Berdoussi ◽  
...  
Keyword(s):  
Statistical Significance ◽  
Linear Regression Analysis ◽  
Thalassemia Major ◽  
Rate Of Change ◽  
Hepatic Iron ◽  
Iron Loading ◽  
Liver Iron ◽  
Cardiac Iron ◽  
Iron Load ◽  
Number Of Patients

Abstract In 212 thalassemia major patients, repeated assessments for cardiac and hepatic iron (LIC) assessed by Magnetic Resonance Imaging (MRI – T2*) have been performed. The chelation regimes were either desferrioxamine (DFO), deferiprone (DFP), combination of DFO and DFP (Comb) or deferasirox (DFX). In general over the last few years, tailoring of chelation therapy has been principally guided by the cardiac iron loading. As many patients had been found to have excess cardiac iron, the majority (48%) had been placed on Comb. Patients were grouped according to the degree of siderosis. A T2* of <1.6ms was regarded as heavy LIC, between 1.6–4.0 moderate, 4.1–9.0 mild and > 9.1 acceptable. Taking into account that the change in T2* is not necessarily linear with respect to time and as the overall time of exposure to DFO, DFP and Comb regimes was significantly greater than that with DFX it was unjustified to perform comparative analysis using the total time period of the patients who were on any of the non DFX regimes. Therefore, to compare the efficacy of the four regimes on LIC, we performed an analysis using student T test to assess the rate of change only between the first and second MRI in patients with comparable LIC according to each chelation regime with adjustment for overall time of exposure (Table 1). Using the same data and applying linear regression analysis (Table 2) we compared the effect of DFO to the other three regimes in the annual rate of increasing hepatic T2*. Only Comb is effective at all levels of hepatic iron loading in reducing the iron content. DFX is effective in the mildly iron loaded patients and for the moderately iron loaded patients, its efficacy approaches statistical significance. DFP does not seem to significantly decrease LIC at any level of hepatic iron load however the numbers of patients in that group are very small. Interestingly DFO seems the least effective at all levels of hepatic iron loading and particularly in the heavy loaded patients. This factor may be related to poor compliance to its use as the patients who have reached such levels of iron load are more often those who are not compliant. In the comparison analysis to DFO, only Comb is significantly better and DFP and DFX are equivalent to it. In addition Comb is more effective than DFX and DFP in that over 12 months it would increase the T2* by 3.8ms (p <0.001) and 3.9ms (p 0.012) respectively. DFX and DFP are similar in efficacy in that they maintain the liver iron at the same levels (DFP vDFX 0.009ms p=0.95). In patients with hepatic T2* >9ms, 4 of 11 on DFO, 5 of 6 on DFX, 7 of 11 on DFP and 3 of 22 on Comb fell below 9. It is of note that DFO only maintains LIC and that a number of patients in the normal range increased LIC. Taking this data into account the DFX and DFP results are compatible with those seen both in the clinic and in trials. It is apparent however that combination therapy is the most effective regime for reducing hepatic iron significantly. As with cardiac iron loading, by knowing the degree of hepatic iron loading by the non-invasive T2* measurement and being able to manipulate patients chelation regimes, it seems possible to be able to have patients free of excess hepatic iron and potentially reduce other iron related morbidities as well. Table 1 Annual estimated mean change in T2* according to severity of hepatic siderosis Regime Heavy Moderate Mild ΔT2* p ΔT2** p ΔT2* p *tm= mean time (in months) between MRI studies DFO n= 42 tm*= 24.6 0.05 0.5 0.57 0.37 0.1 0.7 DFP n= 11 tm= 23.8 0.56 0.25 0.88 0.31 3.5 0.19 Comb n= 101 tm=21.7 1.17 0.0064 3.6 <0.001 5.9 <0.001 DFX n=58 tm=15.2 3.1 0.11 1.25 0.06 3.8 0.014 Table 3 Mean estimated difference in T2* Standard Error p DFP v. DFO −0.7 1.6 0.7 Comb v DFO 3.1 1.05 0.03 DFX v DFO −0.7 1.2 0.5

Efficacy of Iron Chelation in Reducing Cardiac Iron as Assessed by MRI T2* in Patients with Thalassemia Major

Blood ◽  
2008 ◽  
Vol 112 (11) ◽  
pp. 3887-3887
Author(s):  
Vasilios Antonios Berdoukas ◽  
Giorgos Chouliaras ◽  
Panagiotis Moraitis ◽  
Kirikos Zannikos ◽  
Eleni Berdoussi ◽  
...  
Keyword(s):  
Linear Regression Analysis ◽  
Thalassemia Major ◽  
Rate Of Change ◽  
The Other ◽  
Total Period ◽  
Cardiac Iron ◽  
Cardiac Siderosis ◽  
Mri Studies ◽  
Number Of Patients ◽  
Time Varying Covariates

Abstract 241 thalassemia major patients have had repeated evaluation of cardiac iron assessed by Magnetic Resonance Imaging (MRI) over a median interval of 15 months (range 2.6–72.6). We compared changes in T2* between MRI studies with desferrioxamine (DFO) – (number of patients (n)=31, total MRIs (nMRI)=116), deferiprone (DFP) − (n=41 nMRI=94) and combination of DFO and DFP (Comb) − (n=143 nMRI=347) using repeated measurement analysis with correlated error terms and time varying covariates. Patients were divided into four groups according to their baseline cardiac T2* (Heavy load £ 8 ms, moderate load 8–14, mild 314–20 and normal 320). Table 1 shows the overall assessment excluding patients on DFX. These were not included in that assessment as the total period of exposure was statistically significantly less than that of the other regimes. Analysis was therefore performed using student T test to assess the rate of change between the first and second MRI in the T2* values in patients with comparable cardiac siderosis according to each chelation regime adjusted for overall time of exposure (Table 2). With linear regression analysis (Table3) we compared the effect of DFO to the other three regimes in the annual rate of increasing cardiac T2*. The results have been adjusted for baseline T2* and time of exposure to therapy. Both DFP and Comb regimes are superior to DFO in reducing cardiac siderosis. This indicates that over one year DFP and Comb regimes will have a greater increase in T2* than that achieved by DFO. In addition, Comb seems to be superior to DFX as it would increase the T2* by 2ms/year above that which can be achieved by DFX (p=0.007). DFP achieves 1.7ms/year above the annual improvement with DFX but the difference is not statistically significant. The estimated difference in annual improvement of T2* between Comb and DFP is 0.33ms/year (p=0.07) These data confirm that which is seen in clinical practice according to the chelation regimes used. It is clear that the combination of DFO and DFP is the most rapid regime for reducing cardiac iron and seems to be effective at all levels of cardiac siderosis. The ability to assess tissue iron in the heart is extremely clinically valuable and allows preemptive intervention in order to reduce cardiac morbidity and mortality by the selection of the most appropriate chelation therapy according to the MRI findings. Table1 Annual estimated mean change in T2* according to severity of cardiac siderosis Regime Heavy Moderate Mild ΔT2* p ΔT2* p ΔT2* p DFO 0.61 n.s 1.06 n.s. −1.5 n.s. DFP 0.55 <0.001 2.8 <0.001 3.4 <0.001 Comb 1.4 <0.001 3.5 <0.001 2.6 <0.001 Table 2 Annual estimated mean change in T2* according to severity of cardiac siderosis Regime Heavy Moderate Mild ΔT2* P ΔT2* p ΔT2* p *tm= mean time (in months) between MRI studies DFO n= 73 tm*= 23 0.73 0.05 1.07 0.09 0.9 0.4 DFP n= 53 tm=18.5 1.95 0.14 3.2 0.0045 3.9 0.06 Comb n= 152 tm=21.2 1.98 <0.001 4.4 <0.001 5.7 0.0025 DFX n=96 tm=14.9 −0.51 0.41 −0.67 0.4 4.2 0.23 Table 3 Mean estimated difference in T2* Standard Error p DFP v. DFO 2.1 0.99 0.033 Comb v DFO 2.4 0.69 <0.001 DFX v DFO 0.44 0.82 0.6

scholarly journals Correlation between Changes in Cardiac Iron and Hepatic Iron in Pediatric Patients with Thalassemia Major

Blood ◽  
2019 ◽  
Vol 134 (Supplement_1) ◽  
pp. 2241-2241
Author(s):  
Alessia Pepe ◽  
Antonella Meloni ◽  
Aldo Filosa ◽  
Laura Pistoia ◽  
Tommaso Casini ◽  
...  
Keyword(s):  
Iron Overload ◽  
Statistical Significance ◽  
Iron Concentration ◽  
Good Control ◽  
Thalassemia Major ◽  
Hepatic Iron ◽  
Myocardial Iron ◽  
Liver Iron ◽  
Cardiac Iron ◽  
Mri Study

Introduction. A prospective magnetic resonance imaging (MRI) study demonstrated a good control of myocardial iron overload (MIO) in terms of prevention and treatment in children with thalassemia major (TM). The aim of the present study was to evaluate if changes in MIO were related to baseline hepatic iron or changes in hepatic iron overload (HIO). Methods. We considered 68 TM patients enrolled in the MIOT (Myocardial Iron Overload in Thalassemia) project with less than 18 years at the first MRI scan and who performed a follow-up (FU) study at 18±3 months. Myocardial and hepatic iron burdens were quantified by the T2* technique. The value of 20 ms was used as conservative normal value for the global T2* value. Liver T2* values were converted into liver iron concentration (LIC) values. A LIC<3 mg/g/dw indicated significant no HIO, between 3 and 7 mg/g/dw mild HIO, between 7 and 15 mg/g/dw moderate HIO, and ≥15 mg/g/dw severe HIO. Results. Thirty-six patients were females and mean age at the time of the baseline MRI was 13.74±3.09 years. Baseline global heart T2* values were 29.72±11.21 ms and 16 (23.5%) patients showed significant baseline MIO. The percentage changes in global heart T2* values per month in the whole patient population were 0.66±1.70 and they resulted significantly higher in the 16 patients with significant baseline MIO versus the patients with no baseline MIO (1.99±2.53% vs 0.25±1.09% ms; P=0.002). Percentage changes in global heart T2* values per month were not influenced by initial MRI LIC values (R=0.048; P=0.695) (Figure 1A) and were comparable among the 4 groups of patients identified on the basis of baseline MRI LIC values (14 no HIO: 0.29±1.12% vs 21 mild HIO: 0.75±1.56% vs 15 moderate HIO: 0.82±2.03% vs 18 severe HIO: 0.71±2.00%; P=0.876). Percentage changes in global heart T2* values per month were not associated to final MRI LIC values (R=-0.134; P=0.277) (Figure 1B). The correlation between % changes in global heart T2* and MRI LIC values did not reach the statistical significance (R=-0.244; P=0.067) (Figure 1C). In patients with baseline MIO no correlation was found between % changes in global heart T2* values per month and initial MRI LIC values (R=-0.325; P=0.219) or % changes in MRI LIC values per month (R=-0.353; P=0.180). Conclusion. In pediatric TM patients changes in cardiac iron are not correlated to baseline MRI LIC values and changes in hepatic iron. So, our data seem not supporting the hypothesis for which it is necessary to clean the liver before removing iron from the heart. Figure 1 Disclosures Pepe: Chiesi Farmaceutici S.p.A., ApoPharma Inc., and Bayer: Other: No profit support.

scholarly journals Pancreatic iron loading predicts cardiac iron loading in thalassemia major

Blood ◽  
2009 ◽  
Vol 114 (19) ◽  
pp. 4021-4026 ◽  
Author(s):  
Leila J. Noetzli ◽  
Jhansi Papudesi ◽  
Thomas D. Coates ◽  
John C. Wood
Keyword(s):  
Chelation Therapy ◽  
Early Recognition ◽  
Young Patients ◽  
Thalassemia Major ◽  
Iron Deposition ◽  
Iron Loading ◽  
Resonance Imaging ◽  
Liver Iron ◽  
Cardiac Iron ◽  
Negative Predictor

Abstract Diabetes mellitus and cardiomyopathy are common in chronically transfused thalassemia major patients, occurring in the second and third decades of life. We postulated that pancreatic iron deposition would precede cardiac iron loading, representing an environment favorable for extrahepatic iron deposition. To test this hypothesis, we examined pancreatic and cardiac iron in 131 thalassemia major patients over a 4-year period. Cardiac iron (R2* > 50 Hz) was detected in 37.7% of patients and pancreatic iron (R2* > 28 Hz) in 80.4% of patients. Pancreatic and cardiac R2* were correlated (r2 = 0.52), with significant pancreatic iron occurring nearly a decade earlier than cardiac iron. A pancreatic R2* less than 100 Hz was a powerful negative predictor of cardiac iron, and pancreatic R2* more than 100 Hz had a positive predictive value of more than 60%. In serial analysis, changes in cardiac iron were correlated with changes in pancreatic iron (r2 = 0.33, P < .001), but not liver iron (r2 = 0.025, P = .25). As a result, pancreatic R2* measurements offer important early recognition of physiologic conditions suitable for future cardiac iron deposition and complementary information to liver and cardiac iron during chelation therapy. Staging abdominal and cardiac magnetic resonance imaging examinations could significantly reduce costs, magnet time, and need for sedation in young patients.

Vitamin D Deficiency Is Associated with Cardiac Iron Loading in Thalassemia Major.

Blood ◽  
2007 ◽  
Vol 110 (11) ◽  
pp. 574-574
Author(s):  
John C. Wood ◽  
Susan Claster ◽  
Susan Carson ◽  
Khanna Rachna ◽  
Thomas Hofstra ◽  
...  
Keyword(s):  
Vitamin D ◽  
Multivariate Analysis ◽  
Vitamin D Deficiency ◽  
Transferrin Saturation ◽  
Thalassemia Major ◽  
Left Ventricular ◽  
Left Ventricular Ejection ◽  
Iron Loading ◽  
Liver Iron ◽  
Cardiac Iron

Abstract Vitamin D deficiency is epidemic in the United States and is associated with decreased calcium absorption and metabolism, leading to bone loss, muscle weakness, and impaired pancreatic function. Many thalassemia major patients, as a result of decreases sunlight exposure and increased metabolic demand, are vitamin D deficient. We hypothesized that vitamin D deficiency might be associated with cardiac siderosis and impaired cardiac function through its modulation of calcium signaling in these patients. Methods: Permission for review of medical records was obtained from the Committee on Clinical Investigation at Children’s Hospital Los Angeles. We compared vitamin D25-0H and D1-25 levels in our thalassemia major patients with cardiac R2* (1/T2*) and left ventricular ejection fraction (LVEF) from the patient’s most recent cardiac MRI. Time difference between the exams was 2.8 ± 3.3 months with a range of 0.2 to 9.4 months. Other parameters recorded included age, gender, ferritin, liver iron (by MRI) and transferrin saturation. Univariate and multivariate regression was performed using JMP 5.1 (SAS, Cary, NC). Results: Twenty four patients had records suitable for review. There were 11 women and 13 men with a mean age of 14.7 ± 7.6 years [1.4 – 25.8]. Population was moderately iron overloaded with ferritin values of 2089 ± 1920 ng/ml [246 – 8230], liver iron 13.7 ± 11.4 mg/g dry wt [2–39.5], cardiac R2* 65 ± 61 Hz [19.8 – 229], and transferrin saturation 84 ± 18% [36%–106%]. Vitamin D25-OH levels were markedly depressed, 17.1 ± 8.5 pg/ml [1–33], with 13/24 values below the lower limit of 20 ng/ml. Surprisingly, vitamin D1-25OH levels were normal or elevated in all patients, 59.9 ± 19.5 pg/ml [32–103] with four patients exceeding the upper limit of normal of 71 pg/ml. There was no correlation between D25-0H and D1-25OH levels. D25-OH levels (but not D1-25OH levels) fell sharply with age (r2 = 0.48) and were negatively associated with liver iron (r2 = 0.20). Figures 1 and 2 demonstrated cardiac R2* and LVEF as functions of D25-OH levels. Cardiac R2* was log-linearly correlated with D25-OH level (r2 = 0.44, p=0.0001; levels below 13 ng/ml were associated with severe cardiac iron loading. Multivariate analysis of D25-OH, D1-25, HIC, ferritin, age, and transferrin saturation demonstrated that D25-0H and ferritin are the sole predictors of abnormal cardiac R2*, accounting for 38% and 5% of the variability respectively. LVEF was also negatively related to D25-OH levels (r2 = 0.35, p = 0.002). In multivariate analysis, vitamin D250H and vitamin D1-25OH levels accounted for 50% of the LVEF variability, independent of cardiac R2*. Conclusion Vitamin D deficiency is common in thalassemia major patients and strongly associated with cardiac iron uptake and ventricular dysfunction. Figure Figure Figure Figure

A MRI Prospective Survey on Cardiac and Hepatic Iron and Cardiac Function in Thalassemia Major Patients Treated with Sequential deferiprone–desferrioxamine versus Deferasirox

Blood ◽  
2011 ◽  
Vol 118 (21) ◽  
pp. 1087-1087
Author(s):  
Alessia Pepe ◽  
Antonella Meloni ◽  
Giuseppe Rossi ◽  
Domenico Giuseppe D'Ascola ◽  
Marcello Capra ◽  
...  
Keyword(s):  
Cardiac Function ◽  
Iron Overload ◽  
Right Ventricular ◽  
Systolic Function ◽  
Thalassemia Major ◽  
Ventricular Ejection ◽  
Hepatic Iron ◽  
Myocardial Iron ◽  
Liver Iron ◽  
Cardiac Iron

Abstract Abstract 1087 Introduction: No data are available in literature about possible different changes in cardiac and hepatic iron and in cardiac function in thalassemia major (TM) patients treated with sequential deferipron–desferrioxamine (DFP-DFO) versus deferasirox (DFX). Magnetic Resonance (MR) is the unique non invasive suitable technique to evaluated quantitatively this issue.Our aim was to prospectively assess the efficacy of the DFP-DFO vs DFX in a large cohort of TM patients by quantitative MR. Methods: Among the first 1135 TM patients enrolled in the MIOT (Myocardial Iron Overload in Thalassemia) network, 392 patients performed a MR follow up study at 18 ± 3 months according to the protocol. We evaluated prospectively 35 patients treated with DFP-DFO versus 80 patients treated with DFX between the 2 MR scans. Cardiac iron was evaluated by T2* multiecho multislice technique. Biventricular function parameters were quantitatively evaluated by cine images. Liver iron was measured by T2* multiecho technique. Results: Excellent/good levels of compliance were similar in the two groups (DFP-DFO 97.1% vs DFX 98.8%; P=0.544). Among the patients with no significant myocardial iron overload (MIO) at baseline (global heart T2*≥20 ms), there were no significant differences between groups to maintain the patients without myocardial iron overload (DFP-DFO 96% vs DFX 98%; P=0.536). Among the patients with MIO at baseline, in both groups there was a significant improvement in the global heart T2* value (DFP-DFO: 4.8±3.9 ms P=0.004 and DFX: 3.5±4.7 P=0.001) and a significant reduction in the number of pathological segments (DFP-DFO: −3.2±3.8 P=0.026 and DFX: −2.4±3.8 P=0.003). Only in sequential group there was a significant increment in the left and right ventricular ejection fractions (4.3±5.1% P=0.035 and 6.7±6.6% P=0.017, respectively). The improvement in the global heart T2* was not significantly different between groups. The improvement in the left as well in the right ventricular ejection fractions was significantly different between groups (P=0.009 and P=0.015, respectively) (Figure 1). Among the patients with hepatic iron at baseline (T2*<9.2 ms), only in the DFX group there was a significant improvement in the liver T2* value (2.6±5.3 ms P=0.001). The changes in liver T2* were significantly higher in DFX group than in DFP-DFO (0.5±2.0 ms) group (P=0.030) (Figure 2). Conclusions: In TM patients prospectively no significant differences on cardiac iron were found between sequential DFP–DFO treatment versus DFX in monoterapy, although the DFP-DFO treatment was significantly more effective in improving biventricular global systolic function. Conversely, DFX was significantly more effective in reducing hepatic siderosis. Disclosures: Pepe: Novartis: Speakers Bureau; Apotex: Speakers Bureau; Chiesi: Speakers Bureau. Off Label Use: Association of two chelators commercially available in order to obtain a higher efficacy. Borgna-Pignatti:Apotex: Honoraria; Novartis: Honoraria, Research Funding.

Association Between Cardiac Iron Clereance and Hepatic Siderosis

Blood ◽  
2016 ◽  
Vol 128 (22) ◽  
pp. 4833-4833
Author(s):  
Alessia Pepe ◽  
Laura Pistoia ◽  
Domenico D'Ascola ◽  
Maria Rita Gamberini ◽  
Francesco Gagliardotto ◽  
...  
Keyword(s):  
Iron Overload ◽  
Iron Concentration ◽  
Thalassemia Major ◽  
Hepatic Iron ◽  
Liver Iron Concentration ◽  
Liver Iron ◽  
Cardiac Iron ◽  
Follow Up Study ◽  
Hepatic Iron Overload

Abstract Introduction. The aim of this multicenter study was to evaluate in thalassemia major (TM) if the cardiac efficacy of the three iron chelators in monotherapy was influenced by hepatic iron levels over a follow up of 18 months. Methods. Among the 2551 TM patients enrolled in the MIOT (Myocardial Iron Overload in Thalassemia) network we evaluated prospectively the 98 patients those with an MR follow up study at 18±3 months who had been received one chelator alone between the 2 MR scans and who showed evidence of significant cardiac iron (global heart T2*<20 ms) at the basal MRI. Iron overload (IO) was measured by T2* multiecho technique. We used cardiac R2* (equal to 1000/T2*) because cardiac R2* is linearly proportional to cardiac iron and hepatic T2* values were converted into liver iron concentration (LIC) values. Results. We identified 3 groups of patients: 47 treated with deferasirox (DFX), 11 treated with deferiprone (DFP) and 40 treated with desferrioxamine (DFO). Percentage changes in cardiac R2* values correlated with changes in LIC in both DFX (R=0.469; P=0.001) and DFP (R=0.775; P=0.007) groups. All patients in these 2 groups who lowered their LIC by more than 50% improved their cardiac iron (see Figure 1). Percentage changes in cardiac R2* were linearly associated to the log of final LIC values in both DFX (R=0.437; P=0.002) and DFP groups (R=0.909; P<0.0001). Percentage changes in cardiac R2* were not predicted by initial cardiac R2* and LIC values. In each chelation group patients were divided in subgroups according to the severity of baseline hepatic iron overload (no, mild, moderate, and severe IO). The changes in cardiac R2* were comparable among subgroups (P=NS) (Figure 2). Conclusion. In patients treated with DFX and DFP percentage changes in cardiac R2* over 18 months were associated with final LIC and percentage LIC changes. In each chelation group percentage changes in cardiac R2* were no influenced by initial LIC or initial cardiac R2*. Figure 1 Figure 1. Figure 2 Figure 2. Disclosures Pepe: Chiesi Farmaceutici and ApoPharma Inc.: Other: Alessia Pepe is the PI of the MIOT project, that receives no profit support from Chiesi Farmaceutici S.p.A. and ApoPharma Inc..

Pancreatic Iron Deposition Following the Role of Iron Loading Among Transfusion Dependent Sickle Cell Disease Egyptian Children and Young Adults

Blood ◽  
2019 ◽  
Vol 134 (Supplement_1) ◽  
pp. 4828-4828
Author(s):  
Mohsen Saleh Elalfy ◽  
Khalid Allam ◽  
Ahmed Ibrahim ◽  
Basant Mosaad ◽  
Fatma Soliman Elsayed Ebeid
Keyword(s):  
Young Adults ◽  
Sickle Cell Disease ◽  
Iron Overload ◽  
Sickle Cell ◽  
Serum Ferritin ◽  
Iron Loading ◽  
Cell Disease ◽  
Liver Iron ◽  
Cardiac Iron ◽  
Iron Load

Background: Transfusion in sickle cell disease (SCD) is uncommon but a well-defined practice; either as a replacement in severe anemia or as a prophylactic therapy for its major complications mainly stroke. Differential iron loading in SCD especially the extrahepatic organs is not fully studied. Primary objective is to measure pancreatic iron load among Egyptian transfusion-dependant SCD patients by using MRI T2* relaxometry method. Secondaryobjective is to correlate pancreatic iron load to transfusion iron input, both hepatic and cardiac iron load, trend of serum ferritin. Subjects and Methods: Sixty-six transfusion-dependant SCD child and young adults 8-25 years with more than twenty transfusions before enrollment, non was on regular exchange transfusion; they underwent clinical and laboratory assessments; complete hemogram, serum ferritin and serum amylase. All patients performed MRI examination on a 1.5- Tesla super conductive MR Philips scanner in MRI unit in Ain Shams University Hospital; the study takes about 10 -15 minutes. Radiological quantification of iron overload was performed via simple mathematical models using Microsoft Excel Spread Sheet for heart, pancreas, and kidneys. Results: The mean age of the studied SCD patients were 15.68 ± 7.02 years, they were 35 male (53.0%), 43 of them (65.2%) had positive family history of SCD. All were multiple transfusion; 22 for cardiopulmonary complication and acute chest syndrome (ASC), nine for stroke prevention and 35 for frequent sickling crisis and symptomatic anemia. Most of patients (80.3%) were on chelation therapies that were mainly (92.5%) oral mono-therapy. High frequencies of comorbidities were recorded in the studied cohort; delayed puberty (65.2%), hepatitis C infection (23.1%) and stroke (14.1%). The studied SCD patients had median transfusion index of 120ml/kg/year with mean iron overload per day 0.23 ± 0.15 mg/kg and half of them had serum ferritin > 2500ug/L. Almost two-thirds had moderate to severe liver iron overload with median LIC 11.63 mg/g liver dry weight, none had cardiac iron overload with median cardiac T2* 31 msec and nearly half of them (42.2%) showed marked decrease in signal intensity of renal cortex with relative sparing of the renal medulla and pelvis. Most of them (86%) had normal to mild pancreatic iron overload with median pancreatic R2* 53.8 msec. Pancreatic R2 level was not significantly correlated to either transfused iron, liver iron or serum ferritin and amylase. Patients with moderate to severe pancreatic iron overload had lower pre-transfusion hemoglobin level (p=0.004), higher level of marker of hemolysis (total bilirubin (p=0.012) and indirect bilirubin (p=0.048) than those with normal pancreatic MRI. Radiological quantification of iron overload was performed via a simple cheap and quick method for analysis of data. Conclusion: Moderately heavy transfused patients with SCD had no iron overload in the heart; pancreas follow same pattern as heart with minimal or no pancreatic iron loading, however moderate to severe hepatic iron loading. Whether iron loading might be related only to frequency of transfusion or also to frequency of vaso-occlusive will be discussed. Disclosures No relevant conflicts of interest to declare.

Changes in MRI-Estimated Cardiac and Hepatic Iron Load in β-Thalassemia Patients Treated with Deferasirox at a Single Institution

Blood ◽  
2008 ◽  
Vol 112 (11) ◽  
pp. 5418-5418
Author(s):  
Antonios Kattamis ◽  
Panayiotis Moraitis ◽  
Athanasia Lourida ◽  
Efthemia Rigatou ◽  
Vassilios Ladis
Keyword(s):  
Ejection Fraction ◽  
Iron Overload ◽  
Iron Chelation ◽  
Time Interval ◽  
Hepatic Iron ◽  
Single Institution ◽  
Liver Iron ◽  
Cardiac Iron ◽  
Day Range ◽  
Iron Load

Abstract Chronic transfusions have dramatically improved the life expectancy of patients with β-thalassemia, but leads to severe iron overload. Long-term iron chelation therapy aims both in the prevention and the reversal of iron load and iron toxicity. The available chelators seem to have different profiles of relative heart and liver iron removal. Data on cardiac efficacy of deferasirox (DFX; Exjade®) are limited. We report results on patients with thalassemia, followed in a single institution, who completed at least 12 months of treatment with deferasirox. Methods: Fifty five patients (22 males, 33 females; mean age: 27±7.1 years, splenectomised: 5 patients, HCV seropositive: 7 patients) were included in the study. The patients were treated with deferasirox at a mean dose of 27.2±5.2 mg/kg/day (range 15–40 mg/kg/day). Sixty-one pairs of MRI assessments of cardiac and hepatic iron overload by using the T2* technique were performed at a mean time interval of 13.7±2.4 months. Cardiac function parameters, mainly ejection function (EF), were also estimated at the same time. Results: Mean, SD and range at the time of the first MRI evaluation showed: ferritin: 2520±1584 ng/mL (371–6953 ng/mL), cardiac T2*: 25.3±10.7 ms (3.8–39.2ms), liver T2*: 4.5±4.6 ms (0.57–21.1ms) and ejection fraction: 66.9±4.8 ms (55.5–75.4%). Follow up assessments showed: ferritin: 2375±1743 ng/mL (39–7245 ng/mL), cardiac T2*: 27,1±11.7 ms (2.7–40.8ms), liver T2*: 6.2±6.2 ms (0.5–26.4ms) and ejection fraction: 66.1±4.8 ms (55.8–75.4%). Changes in liver and cardiac T2* were statistically significant (p=0.0004 and 0.008, respectively). Changes of the cardiac T2* values correlated well with the dose of deferasirox, while changes of liver T2* with ferritin changes (r=−0.284, p=0.032, r=−0. 27 and p=0.046, respectively). A statistical significant improvement (p&lt;0.05) in cardiac and hepatic iron load was observed in the subgroup of 22 patients with severe liver iron load (defined as hepatic T2*&lt;1.9 ms). In 18 patients with moderate/severe cardiac iron load (cardiac T2*&lt;20ms), T2* decreased in 5, remained stable in 2 and improved in 11 patients (mean 10.7±5.5 ms vs. 12.1±7.1, p=0.078).[S1] Conclusions: This observational study shows that treatment with deferasirox improves both hepatic and cardiac iron overload in regularly transfused β-thalassemia patients. Adjustment of the dose is required to enhance iron excretion and achieve better negative iron balance

Liver and Cardiac Iron Measurements in Very Young Chronically Transfused Patients Show Dangerous Levels of Iron Loading

Blood ◽  
2011 ◽  
Vol 118 (21) ◽  
pp. 1086-1086
Author(s):  
Vasilios Berdoukas ◽  
Mammen Puliyel ◽  
Adam Bush ◽  
Thomas Hofstra ◽  
Bhakti P. Mehta ◽  
...  
Keyword(s):  
Iron Overload ◽  
Research Funding ◽  
Iron Status ◽  
Iron Concentration ◽  
Thalassemia Major ◽  
Iron Loading ◽  
Liver Iron ◽  
Body Iron ◽  
Cardiac Iron ◽  
Total Body

Abstract Abstract 1086 Recurrent blood transfusion results in significant iron overload that can cause serious organ damage and death if not properly treated. Liver iron concentration (LIC) is the best indicator of total body iron status and can be measured non-invasively by magnetic resonance imaging (MRI). In the past, it was recommended that LIC assessments by liver biopsy begin after about 6 years of age (yo). MRI is also an excellent way to monitor iron cardiomyopathy, which remains a major cause of death in chronically transfused patients. To understand how rapidly iron overload develops, we reviewed the 1316 MRI iron studies we have performed since 2002 and summarized the LIC and cardiac R2* in a subset of 127 subjects who had their first MRI studies before 10 yo. Because of the known serious pitfalls in the assessment of total body iron by measurement of ferritin, LIC is measured by MRI in our center as standard of care in all patients on chronic transfusion soon after the start of iron chelation therapy. Most children less than 6 years of age require general anesthesia for this procedure. In some older children cooperation can be achieved by distraction techniques. Thirty three percent had sickle cell disease (SCD), 33% thalassemia major (TM), 11% Blackfan Diamond anemia (DBA), 3% congenital dyserythropoietic anemia (CDA), and 8.6% had other transfusion dependent anemias (OTRAN) and 11.4% had studies done not related to transfusion. This paper will focus on the 114 subjects whose MRI was done to evaluate transfusion related iron overload. The median age at first MRI was 6 years with 25% having their first study before 3.7and 10% before 2.1 yo. The median LIC was 9.8 mg/g dry weight (dw) and 10% of subjects had a first LIC > 22 mg/g dw. Only 2.5% had evidence of cardiac iron (T2* < 20ms). The median LICs (mg/g dw) were 8.9 for SCD, 11.8 for TM, 13 for DBA, 6.1 for CDA, and 8.7 OTRAN and were not statistically different. The minima ranged from 0.6 in OTRAN to 4.2 for CDA and the maxima ranged from 25 in CDA to 39.7 for SCD. There was significant iron loading even when we restricted the analysis to 27 subjects with a first MRI at < 3.5 yo; SCD (2.3 median (med), 2.8 maximum (max)), TM (14.6 med, 35 max), DBA (13 med, 15 max),CDA (6.6 med, 25 max) and OTRAN (5.8 med, 11 max). There were 4 subjects who had evidence of cardiac iron loading. Two had DBA with T2* of 18 ms and 16 ms at 2.5 and 3.7 years of age respectively. A third DBA subject had a T2* of 20 ms at only 4.6 yo. Two TM subjects had a T2* of 15 ms at 6.6 and 9.1 yo respectively. These data indicate that there is significant elevation in LIC by the age of 3.5 years with a median LIC of 11 mg/g dw and 25% of subjects having a LIC > 15 mg/g dw. These are very high levels of iron loading. Furthermore, 2.5% of subjects in this age already have evidence of cardiac iron loading. On the basis of such findings, direct measurement of liver iron by MRI is essential as soon as possible after the start of regular transfusions and cardiac iron should be measured early in high risk children with Diamond Blackfan anemia and thalassemia major. Disclosures: Berdoukas: ApoPharma Inc.: Consultancy. Carson:ApoPharma Inc.: Honoraria; Novartis Inc: Speakers Bureau. Wood:Novartis: Research Funding; Ferrokin Biosciences: Consultancy; Cooleys Anemia Foundation: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding. Coates:Novartis Inc: Speakers Bureau.

MRI Prospective Survey on Cardiac and Hepatic Iron in Thalassemia Intermedia Patients Treated with Desferrioxamine, Deferiprone and Deferasirox

Blood ◽  
2014 ◽  
Vol 124 (21) ◽  
pp. 4041-4041
Author(s):  
Antonella Meloni ◽  
Aurelio Maggio ◽  
Anna Pietrapertosa ◽  
Pier Paolo Bitti ◽  
Sabrina Armari ◽  
...  
Keyword(s):  
Iron Overload ◽  
Iron Concentration ◽  
Iron Chelation ◽  
Hepatic Iron ◽  
Thalassemia Intermedia ◽  
Liver Iron ◽  
Cardiac Iron ◽  
Number Of Patients ◽  
Mri Scans ◽  
Magnetic Resonance Imaging Mri

Abstract Background. Few studies have evaluated the efficacy of iron chelation therapy in thalassemia intermedia (TI) patients. Our study aimed to prospectively assess by quantitative Magnetic Resonance imaging (MRI) the efficacy of the three available chelators in monotherapy in transfusion dependent (TD) TI patients. Methods. Among the 325 TI patients enrolled in the MIOT (Myocardial Iron Overload in Thalassemia) network, we selected 103 TI patients TD with an MRI follow-up (FU) study at 18±3 months who had been received one chelator alone between the two MRI scans. Iron overload was assessed by the T2* multiecho technique. Hepatic T2* values were converted into liver iron concentration (LIC) values. Results. Three groups of patients were identified: 27 patients (13 females, mean age 40.12±10.31 years) treated with desferioxamine (DFO – mean dosage 37.52±8.69 mg/kg/die), 23 patients (14 females, mean age 34.73±10.67 years) treated with deferiprone (DFP– dosage 71.70±14.46mg/kg/die) and 14 patients (9 females, mean age 36.63±10.92 years) treated with deferasirox (DFX – mean dosage 27.75±5.04 mg/kg/die). Excellent/good levels of compliance were similar in the DFO (92.6%), DFP (100%) and DFX (100%) groups (P=0.345). The mean starting age of regular transfusion was 14.73±15.89 years. At baseline in DFO group two patients (7.4%) showed a global heart T2*<20 ms and one of them showed no cardiac iron at the FU. At baseline in DFP group two patients (8.7%) showed a global heart T2*<20 ms and one of them showed no cardiac iron at the FU. All the 5 patients (35.7%) under DFX therapy with pathological global heart T2* at the baseline remained at the same status at the FU. The percentage of patients who maintained a normal global heart T2* value was comparable for DFO (100%), DFP (100%) and DFX (88.9%) groups (P=0.164). Among the 46 patients with hepatic iron at baseline (MRI LIC ≥3 mg/g/dw), the reduction in the MRI LIC values was significant only in the DFO group (DFO: -3.39±6.38 mg/g/dw P=0.041; DFP: -2.25±6.01 mg/g/dw P=0.136 and DFX: -0.36±5.56 mg/g/dw P=0.875). The decrease in MRI LIC values was comparable among the groups (P=0.336). The number of patients with a MRI LIC<3 mg/g/dw went up from 10 (37%) to 11 (40.7%) in the DFO group, from 6 (26.1%) to 8 (34.8%) in the DFP group and from 2 (14.3%) to 8 (57.1%) in the DFX group. The percentage of patients who maintained a normal MRI LIC value was comparable for DFO (90%) vs DFP (50%) and DFX (100%) groups (P=0.191). Conclusion: Prospectively in transfusion-dependent TI patients at the dosages used in the clinical practice, DFO and DFP showed 100% efficacy in maintaining a normal global heart T2* value while DFX had 100% efficacy in maintaining a normal LIC value. Further prospective studies involving more patients with iron at the baseline are needed to establish which is the most effective drug in reducing iron levels. Figure 1 Figure 1. Figure 2 Figure 2. Disclosures Pepe: Chiesi: Speakers Bureau; ApoPharma Inc.: Speakers Bureau; Novartis: Speakers Bureau.

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