Comparison of biventricular dimensions and function between pediatric sickle‐cell disease and thalassemia major patients without cardiac iron

Patients with chronic anemia develop compensatory ventricular dilation, even when maintained on chronic transfusion regimens. It is important to characterize these effects to interpret pathological changes in cardiac dimensions and function introduced by iron overload and sickle cell vasculopathy. Our primary goal was to compare biventricular dimensions and function assessed by cardiovascular magnetic resonance (CMR) in pediatric, chronically‐transfused sickle‐cell disease (SCD) and thalassemia major (TM) patients who had normal cardiac iron levels. Moreover, we explored systematic sex differences in ventricular dimensions in both populations. We identified 261 studies suitable for analysis from 64 patients with SCD (34 females) and 49 patients with TM (20 females). All demographic and CMR parameters were inversely weighted by the number of exams. In both populations, males had larger left and right ventricular dimensions than females, with a more marked effect observed in patients with SCD. Compared to patients with TM, patients with SCD showed significantly greater biventricular dilation and left ventricular hypertrophy. This difference could not be explained by different hemoglobin levels, cardiac iron overload, and systolic blood pressure. The left ventricular (LV) ejection fraction (EF) for the males and the right ventricular (RV) EF for both the sexes were comparable between SCD and TM groups, while females with SCD had significantly lower LV EF than females with TM. Our results represent important baseline findings that place changes introduced by iron overload as well as systemic and pulmonary vasculopathy in proper context. Am. J. Hematol. 88:213–218, 2013. © 2012 Wiley Periodicals, Inc.     

Patterns of liver iron accumulation in patients with sickle cell disease and thalassemia with iron overload

The rate and pattern of iron deposition and accumulation are important determinants of liver damage in chronically transfused patients. To investigate iron distribution patterns at various tissue iron concentrations, effects of chelation on hepatic iron compartmentalization, and differences between patients with sickle cell disease (SCD) and thalassemia major (TM), we prospectively investigated hepatic histologic and biochemical findings in 44 patients with iron overload (35 SCD and 9 TM). The median hepatic iron content (HIC) in patients with TM and SCD was similar at 12.9 and 10.3 mg Fe/g dry weight, respectively (P = 0.73), but patients with SCD had significantly less hepatic fibrosis and inflammation (P < 0.05), less hepatic injury, and significantly less blood exposure. Patients with SCD had predominantly sinusoidal iron deposition, but hepatocyte iron deposition was observed even at low HIC. Chelated patients had more hepatocyte and portal tract iron than non‐chelated ones, but similar sinusoidal iron deposition. These data suggest that iron deposition in patients with SCD generally follows the traditional pattern of transfusional iron overload; however, parenchymal hepatocyte deposition also occurs early and chelation removes iron preferentially from the reticuloendothelium. Pathophysiological and genetic differences affecting iron deposition and accumulation in SCD and TM warrants further investigation ( http://www.clinicaltrials.gov # NCT00675038).     

The differential diagnosis of splachnic vein thrombosis – response to Chatziantoniou & Hunt

The age at which it is necessary to start Cardiovascular Magnetic Resonance (CMR) T2* screening in thalassaemia major (TM) is still uncertain. To clarify this point, we evaluated the prevalence of myocardial iron overload (MIO), function and fibrosis by CMR in TM patients younger than 10 years. We retrospectively selected 35 TM patients enrolled in the Myocardial Iron Overload in Thalassaemia network. MIO was measured by T2* multislice multiecho technique. Biventricular function parameters were evaluated by cine images. To detect myocardial fibrosis, late gadolinium enhancement images were acquired. Patients’ age ranged from 4·2 to 9·7 years. All scans were performed without sedation. Nine patients showed no MIO, 22 patients had heterogeneous MIO with a T2* global value ≥20 ms; two patients had heterogeneous MIO with a T2* global value <20 ms and two patients showed homogeneous MIO. No patient showed myocardial fibrosis. Among the patients with heart T2*<20 ms, the youngest was 6 years old, none showed heart dysfunction and the iron transfused was <35 g in all cases. Cardiac iron loading can occur much earlier than previously described. The first cardiac T2* assessment should be performed as early as feasible without sedation, especially if chelation is started late or if poor compliance is suspected.     

No evidence for myocardial iron overload and free iron species in multitransfused patients with sickle/β0‐thalassaemia

Iron overload (IO) in the heart is a life‐threatening complication in transfusion‐dependent patients with thalassaemia major (TM) and to a lesser extent in sickle cell disease (SCD), while no data are available in patients with sickle/β⁰‐thalassaemia. Iron deposition in the heart, liver and pancreas was assessed using T2* MRI sequences, as well as free iron species assays – non‐transferrin bound iron (NTBI) and labile plasma iron (LPI), in addition to serum ferritin, percentage transferrin saturation and serum hepcidin, in 10 multitransfused patients (>30 yr) with sickle/β⁰‐thalassaemia. None of the patients had iron deposition in the heart. Three patients had mild, one had moderate, and two had severe liver IO. Two patients had mild iron deposition in the pancreas. In all the patients, serum hepcidin levels were normal – NTBI and LPI were not detected. Possible explanations of these findings are discussed.     

Assessing cardiac and liver iron overload in chronically transfused patients with sickle cell disease

Transfusional iron overload represents a substantial challenge in the management of patients with sickle cell disease (SCD) who receive chronic or episodic red blood cell transfusions. Iron‐induced cardiomyopathy is a leading cause of death in other chronically transfused populations but rarely seen in SCD. Study objectives were to: (i) examine the extent of myocardial and hepatic siderosis using magnetic resonance imaging (MRI) in chronically transfused SCD patients, and (ii) evaluate the relationship between long‐term (over the 5 years prior to enrolment) mean serum ferritin (MSF), spot‐ferritin values and liver iron content (LIC) measured using MRI and liver biopsy. Thirty‐two SCD patients (median age 15 years) with transfusional iron overload were recruited from two U.S. institutions. Long‐term MSF and spot‐ferritin values significantly correlated with LIC by MRI‐R2* (r = 0·77, P < 0·001; r = 0·82, P < 0·001, respectively). LIC by MRI‐R2* had strong positive correlation with LIC by liver biopsy (r = 0·98, P < 0·001) but modest inverse correlation with cardiac MRI‐T2* (r = ?0·41, P = 0·02). Moderate to severe transfusional iron overload in SCD was not associated with aberrations in other measures of cardiac function based on echocardiogram or serum biomarkers. Our results suggest that SCD patients receiving chronic transfusions may not demonstrate significant cardiac iron loading irrespective of ferritin trends, LIC and erythropoiesis suppression.     

Pituitary iron and volume predict hypogonadism in transfusional iron overload

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

Iron overload is a determinant of morbidity and mortality in adult patients with sickle cell disease

Patients with sickle cell disease (SCD) often require blood transfusion starting in early childhood. Multiple blood transfusions on a chronic basis lead to excessive accumulation of iron, especially in adults with sickle cell anemia (SS) that is progressively increasing in size. Blood exchange transfusion and the use of iron chelation therapy may prevent or delay the onset of iron overload. The majority of adults with SS, however, require episodic blood transfusions on a chronic basis and, hence, are at risk to develop iron overload. Recent reports suggest an association between iron overload and organ failure in chronically transfused patients. Patients with SCD and iron overload may thus be at increased risk to develop organ failure compared to those with normal iron stores. In order to clarify this issue we have prospectively collected the following data on our adult patients with SCD between 1978 and 1998: (1) the amount of blood transfused; and (2) the status of iron stores determined with serum ferritin, serum iron, total iron binding capacity (TIBC), and percent transferrin saturation (% Sat). Between 1987 and 1998, 247 adult patients with SS were regularly followed in our sickle cell center. Of these, 152 (62%) were transfused with 4,875 units of red blood cells (RBCs). Transfused patients received an average of 10 units of RBCs per year, which is equivalent to about 2.0 g of iron per year. This does not include transfusions at other institutions or before 1987. About one third of the adult patients with SS had % Sat greater than 50 in the steady state, suggesting iron overload. During painful episodes serum ferritin increased significantly in paired observations. Serum iron and TIBC decreased during painful episode disproportionately so that there was a significant net decrease in % Sat in paired observations. Patients with low values of serum ferritin and % Sat had lower incidence of acute painful episodes (38% v 64%) and organ failure (19% v 71%) than those who had iron overload, respectively. Mortality was significantly higher in the iron overload group: 64% versus 5%, respectively. Taken together, the data indicate that (1) the status of iron stores in adults with SS is best determined by keeping accurate records of the amount of blood transfused and serial determinations of ferritin levels in the steady state; (2) a significant number of adults with SS have iron overload; and (3) iron overload seems to be a predisposing factor of disease severity.     

Assessment of liver and cardiac iron overload using MRI in patients with chronic anemias in Latin American countries: results from ASIMILA study*

ABSTRACT

Objectives: A multicenter, noninterventional, observational study was conducted in the Latin American countries including Argentina, Brazil, Colombia, Mexico, and Venezuela to assess the prevalence of liver and cardiac iron overload using magnetic resonance imaging (MRI) in patients with chronic anemias except thalassemia.

Methods: Patients aged >10 years with transfusion-dependent anemias, except thalassemia, either with <20 units of red blood cell (RBC) transfusions with serum ferritin (SF) levels >2000?ng/mL or with ≥20 units of RBC transfusions regardless of SF level in their lifetime, were enrolled. Iron overload was assessed using MRI.

Results: Among 175 patients included, the majority had sickle cell disease (SCD; 52%), followed by aplastic anemia (AA; 17.7%), myelodysplastic syndrome (MDS; 8.6%), Diamond-Blackfan anemia (DBA; 4%), pure red cell aplasia (1.1%), and others (16.6%). Liver iron overload was observed in 76.4% of patients, while cardiac iron overload was seen in 19.2% when assessed by MRI. The prevalence of iron overload was 80.2% in patients with SCD, 73.3% in MDS, 77.4% in AA, 100% in pure red cell aplasia, 71.4% in DBA, and 68.9% in other transfusion-related disorders. A moderate correlation between liver iron concentration (LIC) and SF was observed in patients with SCD and MDS (r?=?0.47 and r?=?0.61, respectively). All adverse events reported were consistent with the published data for deferasirox or underlying disease.

Conclusion: A high prevalence of iron overload in this patient population in Latin American countries indicates that a better diagnosis and management of iron overload is required in these countries.     

Exercise performance in thalassemia major: Correlation with cardiac iron burden

Exercise performance is decreased in patients with Thalassemia major (TM), but the relative impact of anemia and iron overload on exercise capacity is unknown. We assessed the cardiopulmonary function of 71, well‐transfused TM patients via graded treadmill exercise stress test. All patients underwent MRI of the heart, pancreas, and liver and diagnostic phlebotomy. Patients ranged in age from 13 to 46 years of age. Fifteen patients were excluded from analysis due to submaximal effort. Mean Vo₂max was 83.0% of predicted and was limited by abnormal cardiovascular mechanisms, consisting of a decreased O₂ pulse (86.6% of predicted) in men and decreased maximum heart rate (HR) response (85% of predicted) in women. Patients with hemoglobin less than 12 g/dL had lower O₂ pulse and Vo₂max, regardless of sex. Cardiac iron was negatively associated with maximum HR response and Vo₂max (r² = 0.10 and 0.08, respectively, P < 0.05). Vo₂max was correlated with cardiac R2*, hs‐CRP, sex and hemoglobin in decreasing strength of association. In thalassemia, exercise performance is limited by impaired stroke‐volume reserve in men and blunted HR response in women. Iron toxicity may be mediated through vascular inflammation and direct modulation of HR response to exercise. Am. J. Hematol. 88:193–197, 2013. © 2012 Wiley Periodicals, Inc.     

The Uses and Differences of R2 and R2* in the Determination of Iron Overload in Iron Loaded Thalassemia Patients

Early attempts to use magnetic resonance imaging (MRI) for assessing iron overload in β-thalassemia (thal) patients began more than 20 years ago. With advances in MRI, more quantitative efforts focused on measuring transverse relaxation time rates (R₂ and R₂*) of the liver and/or myocardium. Recently, calibration curves of R₂ and R₂* were reported that allowed one to determine the absolute concentrations of iron in the liver, provided that R₂ and R₂* were determined with the same technique. The difficulty of obtaining sufficient myocardium biopsy samples has prevented similar calibration curves being reported for the myocardium. Preliminary data indicate that liver and myocardium R₂* vs. R₂ plots are similar over a large range of R₂* and R₂ values. Obviously, myocardium biopsy samples are needed to confirm whether myocardium R₂* and R₂ plots vs. iron concentration are similar to those published for the liver. The various methods for determining R₂ and R₂* are discussed. It is suggested to use both R₂* and R₂ for assessing iron overload in the liver and myocardium.     

Nutritional deficiencies in iron overloaded patients with hemoglobinopathies

One of the hallmarks of both sickle cell disease (SCD) and thalassemia major (TM) is accelerated oxidative damage. Decreased antioxidant levels and increased oxidant stress biomarkers are found in both diseases. Although isolated vitamin deficiencies have been reported in TM and nontransfused SCD patients, a comprehensive evaluation of vitamin and trace mineral levels has never been performed in chronically transfused SCD or TM patients. As vitamins and trace minerals may be consumed as a result of chronic oxidative stress; we hypothesized that levels of these compounds would correlate with surrogates of iron overload, hemolysis, and inflammation in chronically transfused patients. Using a convenience sample of our group of chronically transfused patients we studied 43 patients with SCD (17 male, 26 female) and 24 patients with TM (13 male and 11 female). The age range for our patients varied from 1.5 to 31.4 years. Levels of vitamins A, thiamin, B6, B12, C, D, E as well as selenium, zinc, copper, and ceruloplasmin were measured. We found that 40–75% of the patients were deficient in A, C, D and selenium and 28–38% of the patients had low levels of B vitamins and folate. There was little association with iron overload, hemolysis, or inflammation. Although the precise mechanism of these deficiencies is unclear, they may contribute to the morbidity of chronically transfused hemoglobinopathy patients. Am. J. Hematol., 2009. © 2009 Wiley‐Liss, Inc.     

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

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

Iron overload across the spectrum of non‐transfusion‐dependent thalassaemias: role of erythropoiesis,splenectomy and transfusions

Non‐transfusion‐dependent thalassaemias (NTDT ) encompass a spectrum of anaemias rarely requiring blood transfusions. Increased iron absorption, driven by hepcidin suppression secondary to erythron expansion, initially causes intrahepatic iron overload. We examined iron metabolism biomarkers in 166 NTDT patients with β thalassaemia intermedia (n  = 95), haemoglobin (Hb) E/β thalassaemia (n  = 49) and Hb H syndromes (n  = 22). Liver iron concentration (LIC ), serum ferritin (SF ), transferrin saturation (TfSat) and non‐transferrin‐bound iron (NTBI ) were elevated and correlated across diagnostic subgroups. NTBI correlated with soluble transferrin receptor (sTfR ), labile plasma iron (LPI ) and nucleated red blood cells (NRBC s), with elevations generally confined to previously transfused patients. Splenectomised patients had higher NTBI , TfSat, NRBC s and SF relative to LIC , than non‐splenectomised patients. LPI elevations were confined to patients with saturated transferrin. Erythron expansion biomarkers (sTfR , growth differentiation factor‐15, NRBC s) correlated with each other and with iron overload biomarkers, particularly in Hb H patients. Plasma hepcidin was similar across subgroups, increased with >20 prior transfusions, and correlated inversely with TfSat, NTBI , LPI and NRBC s. Hepcidin/SF ratios were low, consistent with hepcidin suppression relative to iron overload. Increased NTBI and, by implication, risk of extra‐hepatic iron distribution are more likely in previously transfused, splenectomised and iron‐overloaded NTDT patients with TfSat >70%.     

Extramedullary hematopoiesis is associated with lower cardiac iron loading in chronically transfused thalassemia patients

The aim of this study was to evaluate, in a large cohort of chronically transfused patients, whether the presence of extramedullary hematopoiesis (EMH) accounts for the typical patterns of cardiac iron distribution and/or cardiac function parameters. We retrospectively selected 1,266 thalassemia major patients who had undergone regular transfusions (611 men and 655 women; mean age: 31.3 ± 8.9 years, range: 4.2–66.6 years) and were consecutively enrolled within the Myocardial Iron Overload in Thalassemia network. The presence of EMH was evaluated based on steady‐state free precession sequences; cardiac and liver iron overloads were quantified using a multiecho T2* approach; cardiac function parameters and pulmonary diameter were quantified using the steady‐state free precession sequences; and myocardial fibrosis was evaluated using the late gadolinium enhancement technique. EMH was detected in 167 (13.2%) patients. The EMH+ patients had significantly lower cardiac iron overload than that of the EMH? patients (P = 0.003). The patterns of cardiac iron distribution were significantly different in the EMH+ and EMH? patients (P < 0.0001), with a higher prevalence of patients with no myocardial iron overload and heterogeneous myocardial iron overload and no significant global heart iron in the EMH+ group EMH+ patients had a significantly higher left ventricle mass index (P = 0.001) and a significantly higher pulmonary artery diameter (P = 0.002). In conclusion, in regularly transfused thalassemia patients, EMH was common and was associated with a thalassemia intermedia‐like pattern of cardiac iron deposition despite regular transfusion therapy. Am. J. Hematol. 90:1008–1012, 2015. © 2015 Wiley Periodicals, Inc.     

Absence of cardiac siderosis by MRI T2* despite transfusion burden,hepatic and serum iron overload in Lebanese patients with sickle cell disease

Background: The use of magnetic resonance imaging (MRI) to detect organ‐specific iron overload is becoming increasingly common. Although hepatic iron overload has been recognized in patients with sickle cell disease (SCD), cardiac iron deposition has only been examined in a few reports. Methods: This was a cross‐sectional study of 23 patients with SCD. Patient charts were reviewed and data collected for drug use, total lifetime transfusions (TLT), transfusion rate (TR), status of the spleen, and comorbid illnesses or infections. Blood samples were obtained for assessment of hemoglobin, serum ferritin, non‐transferrin‐bound iron (NTBI), and liver enzyme levels. Doppler echocardiography was performed to detect pulmonary hypertension (PHT) and assess left ventricular ejection fraction. Cardiac iron levels were measured by MRI T2*. Direct determination of liver iron concentration (LIC) was performed using R2 MRI. In this study, cardiac T2* >20 ms was considered normal. Results: The mean age was 24.4 ± 9.7 yr, with a male to female ratio of 15:8. A total of 9 (49.9%) patients were splenectomized. The mean TR was 14.1 ± 13.2 Units/yr, and the mean hemoglobin level was 9.0 g/dL. PHT was detected in 6 (27.3%) patients, but none had evidence of heart failure. The mean serum ferritin, LIC, and NTBI levels were 997.7 ng/mL, 4.6 mg Fe/g dw, and 1.1 ± 2.2, respectively. TR was a much better predictor of iron burden (LIC, ferritin, NTBI) than TLT. In fact, TR less than 10 Units/yr did not produce significant iron overload reflecting spontaneous losses as high as 0.11 mg/kg/d. None of the patients had evidence of cardiac iron overload (mean cardiac T2* = 37.3 ± 6.2 ms; range: 21.9–46.8 ms). There was also no statistically significant correlation between cardiac T2* values and any of the study variables. Conclusion: Our study demonstrates that TR is a stronger predictor of iron overload than TLT. It also confirms cardiac sparing in patients with SCD, even in subjects with significant transfusion burden, systemic and hepatic iron overload.     

Nontransferrin-bound iron in transfused patients with sickle cell disease

The value of nontransferrin‐bound iron (NTBI) as an index of iron overload in patients with thalassemia has been evaluated; however, data in patients with sickle cell disease (SCD) is limited. NTBI levels were evaluated in a cross‐sectional study of 43 transfused patients with SCD. Patient charts were reviewed for demographics, status of the spleen, and total number of lifetime transfusions. All patients were chelation naïve and none of the patients had evidence of hepatitis B or C infection. Blood samples were taken for assessment of NTBI and serum ferritin (SF); liver iron concentration (LIC) was determined by R2 magnetic resonance imaging. NTBI levels were generally low with a median of ?0.01 μm (range ?2.56 to 6.37 μm ). Among study variables, NTBI levels were only significantly correlated to age and total number of lifetime transfusions, whereas LIC and SF only significantly correlated with total number of lifetime transfusions. On multivariate analysis, only total number of lifetime transfusions remained independently correlated with NTBI (P = 0.001), SF (P < 0.001), and LIC (P < 0.001). On multivariate stepwise linear regression analysis, SF was a better predictor of LIC than NTBI. In transfused patients with SCD, NTBI levels are low yet correlate significantly with transfusion burden. However, they offer poor predictability of LIC when compared with SF.     

Observational study of iron overload as assessed by magnetic resonance imaging in an adult population of transfusion‐dependent patients with β thalassaemia: significant association between low cardiac T2* < 10 ms and cardiac events

Background: Thalassaemia major patients usually die from cardiac haemosiderosis. Improved strategies are required to modify this risk. Aims: To assess the significance of cardiac iron overload in patients with β thalassaemia. Method: Observational study of cardiac iron overload as assessed by magnetic resonance imaging (MRI) cardiac T2* relaxometry in 30 adult patients with transfusion‐dependent β thalassaemia. Results: 11/30 patients (37%) had cardiac T2* < 10 ms, 8/30 (27%) in range 10–20 ms and 11/30 (37%) > 20 ms. There was significant inverse correlation between T2* values and values for serum ferritin (SF) and liver iron concentration (LIC) and positive correlation with left ventricular ejection fraction (LVEF). Median LVEF values were 49% in patients with T2* < 10 ms and 58% in patients with T2* > 10 ms (P= 0.02). Very low T2* values <10 ms were strongly associated with the occurrence of cardiac events (congestive heart failure, arrhythmia, cardiac death): occurring in 5/11 patients with T2* < l0 ms and in 0/19 in patients with T2* > 10 ms (P= 0.003 Fisher's exact test; P= 0.002 log rank Kaplan‐Meier time to event analysis). There was no significant association between T2* < 10 ms or cardiac events and traditional measures of iron overload, such as SF levels >2500 µg/L and LIC (evaluated at thresholds of >7 or >15 mg/g dry weight). Conclusion: Very low cardiac T2* values <10 ms are common in adults with β thalassaemia and are significantly associated with risk of cardiac events. This permits the use of individually targeted chelation strategies which are more effective in removing cardiac iron.     

Red blood cell transfusions are associated with HLA class I but not H‐Y alloantibodies in children with sickle cell disease

Blood transfusions can induce alloantibodies to antigens on red blood cells (RBCs), white blood cells and platelets, with these alloantibodies affecting transfusion and transplantation. While transfusion‐related alloimmunization against RBC antigens and human leucocyte antigens (HLA) have been studied, transfusion‐related alloimmunization to minor histocompatibility antigens (mHA), such as H‐Y antigens, has not been clinically characterized. We conducted a cross‐sectional study of 114 children with sickle cell disease (SCD) and tested for antibodies to 5 H‐Y antigens and to HLA class I and class II. Few patients had H‐Y antibodies, with no significant differences in the prevalence of any H‐Y antibody observed among transfused females (7%), transfused males (6%) and never transfused females (4%). In contrast, HLA class I, but not HLA class II, antibodies were more prevalent among transfused than never transfused patients (class I: 33% vs. 13%, P = 0·046; class II: 7% vs. 8%, P = 0·67). Among transfused patients, RBC alloantibody history but not amount of transfusion exposure was associated with a high (>25%) HLA class I panel reactive antibody (Odds ratio 6·8, 95% confidence interval 2·1–22·3). These results are consistent with immunological responder and non‐responder phenotypes, wherein a subset of patients with SCD may be at higher risk for transfusion‐related alloimmunization.     

Myocardial iron overload assessed by magnetic resonance imaging (MRI)T2* in multi-transfused patients with thalassemia and acquired anemias

Background

Cardiac complications secondary to iron overload remain a significant matter in patients with transfusion dependent anemias.

Patients and methods

To evaluate cardiac siderosis, Magnetic resonance imaging T2* (MRI T2*) was performed in 3 cohorts of transfusion dependent patients: 99 with thalassemia major (TM), 20 with thalassemia intermedia (TI), and 10 with acquired anemias (AA). Serum ferritin was measured and all patients underwent echocardiographic evaluation.

Results

In TM patients cardiac T2* pathologic values (below 20 ms) were found in 37 patients. Serum ferritin was negatively associated with age (r = −0.32, p = 0.001) and weakly with T2* values (r = −0.19, p = 0.057). A positive correlation was found between T2* and LVEF (r = 0.27, p = 0.006). Out of 37 patients with T2* < 20 ms, 18 (48%) had serum ferritin values < 1000 ng/ml. In TI cohort, 3 patients had cardiac T2* pathologic values. In AA cohort, pathologic T2* values were found in 2 patients, who received 234 and 199 PRBC units, respectively, and were both on chelation therapy (in one patient ferritin value was 399 ng/ml). T2* values were negatively associated, but not significantly, with the number of PRBC transfused (r = −0.53, p = 0.07).

Conclusion

In our experience, 37% of TM patients had a myocardial iron overload assessed by MRI T2*; this value is higher than in TI patients. Serum ferritin measurement was a poor predictor of myocardial siderosis. In patients with AA, more than 200 PRBC units transfused were required to induce cardiac hemosiderosis, in spite of chelation therapy and, in one patient, of normal ferritin values.     

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

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