ALBERT

Description: Background: In β-thalassemia major (TM) myocardial iron toxicity is the dominant cause of ventricular dysfunction, with heart failure responsible for the majority of deaths. Abnormal endothelial function has also been described in these patients and could further contribute to cardiovascular complications. Endothelial function can be determined by measurement of flow mediated dilatation of the brachial artery (FMD). This can be assessed reproducibly by cardiovascular magnetic resonance (CMR). Aims: To report the changes in endothelial function, LV ejection fraction and ferritin from a randomized placebo controlled trial comparing combined chelation therapy (deferiprone and deferoxamine) with deferoxamine monotherapy. Methods: 65 patients (male 27, female 38, age 28.7+/−4.8years) with mild-moderate myocardial iron loading (heart T2* 8–20ms) were randomized to receive either deferoxamine with placebo (placebo group), or deferoxamine with deferiprone (combined group). FMD was assessed at baseline and after 12 months. Results: There were significant improvements in endothelial function in the combined treatment group compared with the placebo group (+8.8% vs 3.1% p=0.013). This was in accord with improvements in the combined group in left ventricular ejection fraction (+2.4% vs +0.6%, p=0.02), and serum ferritin (−870 vs −194 μg/L; p

Description: Introduction: Myocardial iron overload is a well established cause of heart failure in a number of haematological disorders and is the leading cause of death in β-thalassaemia major (TM). Once overt heart failure develops prognosis is very poor and it would therefore be desirable to identify patients at risk, prior to the development of symptomatic heart failure. Myocardial iron can now be rapidly and reproducibly assessed using a validated cardiac magnetic resonance (CMR) T2* technique. Left ventricular ejection fraction has been demonstrated to relate to myocardial T2* (normal 〉20ms), and accordingly iron overloaded patients with symptomatic heart failure are likely to have a low T2* but there are no reports of the myocardial T2* level in newly presenting patients with heart failure and the threshold for increased risk is also unknown. Purpose: To establish the distribution of myocardial T2* values in patients presenting with symptomatic heart failure secondary to iron overload. Methods: Database records of CMR T2* assessments over a 5 year period were reviewed to identify iron overloaded patients presenting with heart failure. Results: 28 patients (median age 29y, 11–79) with iron overload and documented heart failure were identified. 22 patients had thalassaemia major, 3 hereditary haemochromatosis, and 3 had miscellaneous transfusion dependent anaemias. The mean myocardial T2* in all groups was 6.8+/− 2.2ms reflecting severe iron loading by clinical criteria. See figure 1. Myocardial T2* values were similar between sub-groups as follows: TM patients 6.7+/− 2.4ms, haemochromatosis 7.7ms (6.7–7.4ms), miscellaneous 6.8ms (4.8–9.1ms). Conclusion: In this database review, the patients developing heart failure secondary to iron overload all had abnormal myocardial T2*, and overall 89% of heart failure patients had values less than 10ms, which reflects severe myocardial iron loading. This data suggests a myocardial T2*

Description: Introduction: Beta thalassaemia major (TM) is a hereditary anaemia affecting 60 000 births worldwide each year. Survival is dependent upon lifelong blood transfusions with cardiac failure secondary to myocardial iron loading being the commonest cause of death. Conventional treatment with the parenteral iron chelator deferoxamine improves mortality but prognosis remains poor and it has been reported that approximately two-thirds of patients maintained on this treatment have myocardial iron loading. More recently, the oral iron chelator, deferiprone has been demonstrated to remove myocardial iron and it has been proposed that in combination with deferoxamine it may have an additive or synergistic effect. Myocardial iron can now be rapidly and reproducibly quantified using the validated cardiac magnetic resonance (CMR) T2* technique. CMR is therefore well suited to assess the efficacy of new therapies for the removal of myocardial iron in TM. Purpose: To report the primary outcome measure (heart T2*) from a randomized placebo controlled trial testing the hypothesis that the combined therapy of deferiprone and deferoxamine is superior in the removal of myocardial iron than the standard therapy of deferoxamine alone. Methods: A mobile CMR scanner (1.5T Siemens Sonata) was transported to Cagliari, Italy on 3 occasions. The myocardial T2* was assessed in 167 patients with TM. 65 patients (male 27, female 38, age 30+/−5.2years) with mild-moderate myocardial iron loading (T2* 8–20ms) were randomized to receive either deferoxamine and placebo, or deferoxamine and deferiprone. The primary outcome measure of myocardial T2* was assessed at baseline, 6 and 12 months. Normal myocardial T2* is greater than 20ms. Results: In the combined treatment group myocardial T2* improved (reducing myocardial iron) from a baseline of 11.7ms to (at 6 months) 14.6ms (+25%; CV 11.9%; p=0.007) and at 12 months 16.8ms (+40%; CV 14.2%; P

Description: Repeated blood transfusions in Thalassemia Major (TM) may lead to myocardial iron accumulation and death. Left ventricular (LV) function is commonly used to assess for iron overload, however, the reference range in TM for these variables in the absence of myocardial iron loading is not known. We used cardiovascular magnetic resonance (CMR) in 205 TM patients and studied those (N=81) with normal myocardial T2* measurements (T2*〉20ms) and by inference without excess myocardial iron. Resting LV volumes and function normalized to body surface area were compared with 40 age and gender matched healthy controls. All LV parameters were significantly different (p

Description: Introduction: Thalassaemia major ™ is an inherited haemoglobinopathy resulting from mutations of the β-globin gene. Survival is dependent upon lifelong blood transfusions and results in progressive total body iron overload. Cardiac failure secondary to myocardial iron loading is by far the commonest cause of death with only 50% of patients in the UK in recent cohorts surviving beyond the age of 35 years. Conventional treatment with the parenteral iron chelator deferoxamine improves morbidity and mortality but fails to clear the heart of iron in approximately two-thirds of patients. More recently, the oral iron chelator deferiprone has been demonstrated to remove myocardial iron and it has been proposed that in combination with deferoxamine it may have an additive effect. Through the T2* multi-echo cardiac magnetic resonance (CMR) technique, myocardial iron can now be non-invasively and reproducibly quantified, thereby providing a means to assess myocardial iron loading in response to chelation treatment. Purpose: To report the changes in myocardial T2* and cardiac function in patients with severe myocardial iron loading (myocardial T2*

Description: Introduction: Beta thalassaemia major (TM) is a hereditary anaemia affecting 60 000 births worldwide each year. Survival is dependent upon lifelong blood transfusions resulting in iron overload. Cardiac siderosis can result in a cardiomyopathy which is the leading cause of death in TM. The validated cardiac magnetic resonance (CMR) T2* technique allows non-invasive and reproducible quantification of myocardial iron. Assessment of myocardial iron loading is essential in determining appropriate chelation therapy. This technique has the potential to become the new gold standard in the assessment of cardiac siderosis but is currently available at only a few sites worldwide. For maximal healthcare benefit its inter-scanner reproducibility must be demonstrated before being widely disseminated. Objective: To demonstrate that CMR T2* quantification of myocardial iron can be reproducibly transferred to MR scanners of different manufacturers in different centres. This project was sponsored by the Thalassemia International Federation. Methods: The previously described multi breath-hold gradient echo T2* technique was installed on MR scanners (all 1.5Tesla) at 6 different centres. Scanner details were as follows: Site 1, Phillips Intera (Turin, Italy), Site 2, Siemens Sonata (Philadelphia, USA), Site 3 GE Signa (Limassol, Cyprus) Site 4, Phillips Intera (Nicosia, Cyprus), Site 5, GE Signa (Cagliari, Sardinia) and Philips Intera (Genova, Italy). 34 patients (mean age 30+/− 5.7years) were scanned in total. All patients were subsequently re-scanned at the standardization centre in London, UK (Siemens Sonata, 1.5T) within 31 days of their original scan. Results: The T2* sequence was successfully installed on all 6 scanners. Myocardial T2* values ranged from 3.6ms to 51ms (14.2 +/− 11ms). The overall inter-scanner reproducibility (SD/mean) was 5.3% (figure 1). The mean difference between T2* values at the standardization centre and visited sites was 0.32ms. Conclusion: We have demonstrated that the multi breath-hold T2* technique for the quantification of myocardial iron can be reproducibly transferred to 1.5T MR scanners at different sites and of different manufacturers. There is therefore real potential to roll out this technique worldwide to facilitate maximal healthcare impact in the management of patients with iron overload conditions such as thalassaemia. Figure Figure