Detailed Description:

Chronic heart failure (HF) is associated, in more than one third of patients, with iron deficiency (ID), and this comorbidity can have a negative impact on quality of life and survival. Treatment of ID is recommended in patients with HF and left ventricle ejection fraction (LVEF) <45% to improve symptoms and reduce rehospitalizations. Intravenous iron supplementation with ferric carboxymaltose (FCM), has been shown to be effective in correcting ID and improving symptoms in patients with HF, therefore, it is considered the standard of care. However, intravenous supplementation is not riskless. The main side effects are as follows: accumulation of circulating non-transferrin bound iron (NTBI), which can lead to increased oxidative stress. increased blood levels of the biologically active form of fibroblast growth factor-23 (FGF-23), especially with the use of FCM. When elevated, this hormone reduces renal phosphate uptake, leading to hypophosphatemia and, consequently, osteomalacia. In patients with chronic kidney disease (CKD), elevated FGF-23 levels have also been associated with left ventricular hypertrophy, myocardial fibrosis, increased adverse cardiovascular events and all-cause mortality, regardless of traditional cardiovascular risk factors. Oral iron supplementation could therefore be safer in patients with HF, reducing oxidative stress and the risk of altered bone metabolism. To date, the only trial that has evaluated the efficacy of oral iron in HF has provided discouraging data. More precisely, hepcidin inhibition on iron intestinal absorption appears to be the most relevant factor affecting the efficacy of iron treatment. To overcome hepcidin blockade, it has been proposed to use specific oral iron formulations, which are less susceptible to inhibition of hepcidin (such as sucrosomial iron), and a single high-dose daily administration. Additionally, the possibility of actively reducing hepcidin levels has been explored by administering compounds that act as hepcidin inhibitors. Among these compounds, one of the most promising is vitamin D. The main hypothesis which the study aims to test is the non-inferiority of sucrosomial iron (± vitamin D) compared with FCM treatment, after 24 weeks. Primary endpoint: the performance of the Six-Minute Walking Test, comparing the mean difference from baseline of the distance walked by patients in meters. Study design Interventional, randomized, controlled, open-label, sequential recruitment study of outpatients, diagnosed with symptomatic chronic HF (New York Heart Association - NYHA class II-III), LVEF≤45%, ID (ferritin <100 ng/ml or transferrin saturation - TSAT <20% in case of ferritin levels between 100 and 300 ng/ml) and hemoglobin (Hb) values between 9.5-13.5 g/dL. In patients hospitalized for acute HF (inpatients), pre-randomization will be performed and re-evaluation for recruitment during outpatient visit will be scheduled at least 3 weeks after discharge. The study will involve randomization into 3 groups with a 1:1:1 ratio: Control group [standard of care]: administration of FCM (Ferinject®) with a dose between 500 and 2000 mg (depending on body weight and Hb values), to be administered in 1 or 2 doses (time 0 ± 6 weeks) with possible additional administration of 500 mg at week 12 in case of persistent ID. Sucrosomial iron group: administration of sucrosomial iron (SiderAl Forte®) at a dose of 60 mg (2 tablets) once a day for 24 weeks. Sucrosomial iron and vitamin D group: administration of sucrosomial iron (SiderAl Forte®) at a dose of 60 mg (2 tablets) once daily + Vitamin D3 (100,000 IU load at time 0, then 2,000 IU daily) for 24 weeks Period of treatment and follow-up The expected duration of subject participation is approximately 27 weeks. The duration of the screening period is up to 3 weeks (although may be longer for subjects rescreened); treatment period is 24 weeks. During treatment, patients will be evaluated in outpatient scheduled visits at 6, 12 and 24 weeks, performing blood tests, clinical evaluation, instrumental investigations and recording any adverse events, cardiovascular events, re-hospitalizations and fractures. After completion of treatment, an echocardiographic evaluation will also be performed to assess parameters of systolic and diastolic function, parietal thicknesses, and left ventricular diameters. Hypothesis Formulation and Testing Procedure The three-arm design with two experimental treatments poses the need to evaluate the effects of sucrosomial iron treatments before comparing them with FCM. The investigators decided to base the comparison of sucrosomial iron with FCM on the results of the non-inferiority test between the two experimental treatments (first non-inferiority test; NIT1). Let's SI= sucrosomial Iron; SID=sucrosomial Iron + Vitamin D; FCM: Ferric carboxymaltose; if non-inferiority is assessed, the investigators will test the pooled experimental group (SID+SI) against the FCM group (second non-inferiority test, version A; NIT2-A), otherwise the investigators will interrupt the study. In the case of the superiority of SID over SI, the investigators will test the non-inferiority of SID (not pooled) over the control treatment (second non-inferiority test, version B; NIT2-B). An interim analysis for NIT1 will be performed at the half of patient enrolment to assess whether to stop for efficacy/futility or continue in patients' enrolment Assumption and sample size The investigators have information from the CONFIRM-HF study that compared the 6MWT-as difference from baseline-of FCM group versus placebo. The FCM group, after 24 weeks, walked an average of 18 meters more than at the baseline, with a standard deviation of 8, while the placebo group walked an average of 16 meters less than at the baseline, with an equal standard deviation of 8. Thus, the investigator assume a standard deviation of 8, equal for the three arms. The ΔNIT1 has been fixed to 3.2 meters and ΔNIT2 equal to 7. Finally, assuming 80% of power, 5% Type I error for both NIT1 and NIT2 (since they have a hierarchical structure), the sample size required for NIT1 is 234. After accounting for potential dropouts (10%), the final calculated sample size is 258 that is adequate to conduct also the subsequent noninferiority hypothesis test, in any case (NIT2-A or NIT2-B)}}