View clinical trials related to Iron Overload.
Filter by:The FeMicrobiome study will evaluate gut microbiome features and their relationships with dietary iron absorption in healthy adults. The investigators hypothesize that (1) the gut microbiota can be shaped by the heme and non-heme Fe content of the diet and that (2) this will influence individual variation in dietary Fe absorption.
Patients with hemochromatosis or Thalassemia develop progressive tissue and organs damages secondary to iron overload. Iron overload can result both from transfusional hemosiderosis and excess gastrointestinal iron absorption. Iron deposition in the heart, liver, and multiple endocrine glands results in severe damage to these organs, with variable degrees of endocrine and organ failure. Although patients with iron overload often present endocrine disorders, the pathogenetic mechanisms underlying endocrinopathies are not completely clear. In particular it is not elucidated if the spectrum of endocrinopathies could change with advancing age. All endocrinological comorbidities can develop from a primary damage of the target gland, from pituitary secondary failure or from both. The aim of this study is to investigate the prevalence of endocrinological diseases in adult patients with iron overload due to β-thalassemia or hemochromatosis and their impact on well-being and quality of life. The study design is a prospective cross-sectional clinical study. All subjects enrolled will be evaluated for the endocrine diseases. The study protocol will include data collection from family and patients' history of diseases, physical examination, hormonal assessment for all endocrine axes and instrumental examinations. The results will provide evidence on the prevalence of endocrine diseases in patients with iron overload and will add information to characterize the type and the degree of endocrine deficiencies, and on the pathogenic mechanisms involved, in order to individualize diagnostic and therapeutic approaches.
The safety and efficacy of CN128 is studied in thalassaemia with sever liver iron overloaded patients.
The purpose of this research is to see if a new automated magnetic resonance imaging (MRI) method will be able to improve the images taken of the liver. Participants will have either known or suspected liver disease, known or suspected iron overload syndrome, or be a healthy adult. Participants will be in the research study for one day.
All patients were investigated using a 3T MRI and 1,5 T MRI scanners. For myocardium, pancreas and pituitary gland iron overload quantification in children we have used special sequences for T2*-mapping. Miocardium, pancreas and pituitary gland T2* relaxometry maps were calculated automatically by commertial application ReportCARD Functool (GE Healthcare) and integrated Philips T2* maps. Then for selected ROI T2* data acquisition in milisecond [ms] were performed and calculated automatically.
The overall goal of this project is to develop and validate a novel technique for Magnetic Resonance Imaging (MRI)-based Quantitative Susceptibility Mapping (QSM) of the abdomen, for non-invasive assessment of liver iron deposition. In this work, study team will develop and optimize advanced data acquisition and image reconstruction methods to enable QSM of the abdomen. Further, investigators will determine the accuracy, repeatability, and reproducibility of abdominal QSM for iron quantification in patients with liver iron overload. Excessive accumulation of iron in various organs, including the liver, which affects both adult and pediatric populations, is toxic and requires treatment aimed at reducing body iron stores. Accurate assessment of liver iron concentration is critical for the detection and staging of iron overload as well as for longitudinal monitoring during treatment. In summary, this project will develop a novel MRI-based QSM technique designed for the abdomen and will validate it in pediatric and adult patients with liver iron overload. Upon successful validation, QSM will provide accurate, repeatable, and reproducible quantification of LIC based on a fundamental property of tissue.
Hematopoietic Stem Cell Transplantation (HSCT) is currently a standard procedure for a wide range of blood-oncological diseases and genetic disorders. Recent improvements in transplant technologies, infection prevention and graft-versus-host-disease (GVHD) management procedures have significantly reduced the transplant-related mortality (TRM). However, approximately 50% of pediatric patients may develop liver dysfunction before HSCT and 74% to 85.5% after HSCT, with a TRM related to liver dysfunction reaching 46%. The liver and pancreas complications still remain too high for the difficulties and diagnostic inefficiencies and, consequently, for the lack of targeted and safer therapies. The diagnostic problems can be summarized in 3 major points: a) the histological examination of liver and pancreas parenchyma cannot be routinely performed because of the organ anatomy and the relative risk of the bioptic procedures; b) the lack of specific biomarkers or advanced imaging techniques appropriate for the diagnosis of HSCT complications; c) the multifactorial causes of organ complications, as well as drug toxicities, GVHD, siderosis, ductopenia (considered as an index of hepatic GVHD), the accumulation of potentially toxic substances favored by siderosis and ductopenia. In more than 50% of HSCT patients, siderosis and/or ductopenia may represent common pathological conditions. Furthermore, international guidelines issued by onco-hematology and transplantation scientific societies recommend a chelating treatment with deferasirox in all hematological and oncological patients undergoing an intense transfusion regimen. However, in the presence of siderosis and marked ductopenia, patients receiving deferasirox may experience both severe renal and hematological toxicities and lack of effectiveness of the chelating treatment. Therefore, the principal aim of the present retrospective study will be the evaluation of the transplant-related mortality (TRM) in patients requiring a chelation treatment according to the Italian guidelines in pediatric patients
Hypothesis: Taurine, in combination with standard iron chelation therapy, is more effective than chelation therapy alone in reducing cardiac iron overload, oxidative stress and cardiac damage in β-Thalassemia. Protocol: Sixty subjects with transfusion dependent β-Thalassemia receiving deferasirox iron chelation therapy will be recruited and randomized in a 1:1 ratio to either (1) placebo and continuation of their iron chelation or (2) a combination of iron chelation plus taurine. Transfusion and safety visits will be scheduled monthly with clinical/biochemical assessment visits every three months. The efficacy of taurine combined with standard chelation therapy will be assessed at baseline and 12 months posttreatment by both cardiac T2*MRI, and cardiac function. The recruitment period is projected to be 12 months from initiation.
This is a randomized, open label, two arms superiority trial of a representative population of patients with a primary diagnosis of transfusion dependent thalassemia with evidence of moderate cardiac iron overload, defined as an average T2* MRI parameter at the mid inter-ventricular septum between 10 and 20ms.
Dysmetabolic iron overload syndrome (DIOS), is a frequent hepatic iron overload associated with metabolic syndrome. We hypothesize that this mild iron overload can induce a increased macrophagic polarization towards inflammatory types, thereby contributing to cardiovascular risk. Our main objective is to highlight the influence of iron overload on polarization capacity of monocytes into alternative macrophages (called M2). We therefore compare phenotypic markers of monocytes/macrophages between subjects with DIOS, metabolic syndrome without iron overload and lean subjects.