View clinical trials related to Beta-Thalassemia.
Filter by:The purpose of this study is to assess safety and amount of the study drug in the blood after increasing doses of SP-420. The study will be conducted in patients with β-thalassemia.
Study A536-06 is an open-label extension study for patients previously enrolled in study A536-04 (ClinicalTrials.gov Identifier NCT01749540), to evaluate the long-term safety and tolerability of ACE-536 in adult patients with beta-thalassemia.
The investigators propose that patients with HbSβ-thalassemia have lower levels of hepcidin and higher levels of GDF-15 than HbSS patients during the non-crisis, "steady states." In addition, the investigators propose that when controlled for RBC transfusion, patients with HbSβ-thalassemia will have higher levels of storage iron (based on serum ferritin). Participants: Total number of subjects is 42 - 21 subjects with HbSS, and 21 subjects with HbSβ-thalassemia ). Procedures (methods): Eligible subjects with documented SCD (HbSS, HbS-β 0-thalassemia or HbS-β+-thalassemia) followed at the University of North Carolina (UNC) Comprehensive Sickle Cell Program will be evaluated in this single-center, prospective, cross-sectional study. The patients will be screened for eligibility at the time of a routine sickle cell clinic visit. Patients' data will be obtained in person at the time of evaluation and through review of their medical records. Investigators will obtain information on SCD-related clinical complications and obtain an estimate of the number of lifetime RBC transfusions. Blood samples will be obtained for laboratory tests. Plasma samples for hepcidin, growth differentiation factor 15 (GDF -15), and high-sensitivity CRP will be stored at -80 degrees Celsius until analysis. Other routine laboratory studies including complete blood count (CBC) with differential and reticulocyte count, serum iron profile and ferritin, and liver function tests will be performed at the clinical laboratories of UNC Hospitals.The subjects will have 30 ml. of blood drawn for this research study. Females of child bearing potential will have a urine pregnancy test at the time of the study.
Background: Three iron chelators now available on the market differ in toxicity and organ specificity; evidence on standardized chelation protocol remains inconclusive, but patients with transfusion-dependent beta-thalassemia treated with DFO infusion show significant differences in the limitations of daily activities, physical activity, and quality of life when treated with oral chelator. With licensing of DFP in America, it is reasonable to combine DFP with DFX. Patients find two oral chelators more acceptable than one oral and one injectable. This pilot study rates use of DFP for improving iron excretion profile of deferasirox. Methods: The investigators enrolled 13 beta-thalassemia patients in China Medical University Children's Hospital in May 2009-October 2011. Five refused to take part in pharmacokinetics; they only participated in iron excretion study. Seven with irregular bowel function were unable to collect feces in the screening period as baseline data. Subjects were randomly assigned and rotated to undergo all treatments (with informed consent): (A) single oral dose of DFX 30 mg/kg once daily, (B) single oral dose of DFP 40 mg/kg twice a day, (C) oral doses of DFX and DFP administered sequentially (DFX 30 mg/kg/d, deferiprone 40 mg/kg/d and deferiprone 40 mg/kg/d at 7-hour intervals). Three-day drug dosage was followed by four-day washout. Collections of urine and stool proceeded 24 hours per day, each analyzed separately. Through a venous catheter, serial blood samples (1 mL/each sampling) were collected in glass tubes containing heparin as anticoagulant at Time 0 (pre-dosing) and at 0.5, 1, 1.5, 2, 2.5, 3, 3.5, 4, 4.5, 6, 7, 8, 10, 12 and 24 hours after dose; plasma concentrations of DFP and DFX were measured.
This is a study to collect the outcomes of stem cell transplantation for patients with hematologic diseases other than cancer.
A prospective randomized study on Safety, Tolerability and Efficacy of oral Low dose DFP (50 mg/kg/day) in minimally transfused B-TM after 5 transfusions when SF reaches 500 ng/m and with either appearance of LPI > 0.2 or TSAT reaches 50% compared with non treatment arm. So the aim of this study: 1. To determine the time as well as amount of transfused iron ( calculated in mg iron/kg ) which lead to Serum ferritin reaches 500 ng /ml and LPI appearance >0.2 as well as TSAT reaches 50 % . 2. Tolerability and safety of early low dose DFP 50mg/kg and effectiveness to postpone or prevent SF from reaching 1000 ng/ml or LPI >0.6 or TSAT >70% in comparison to patients not starting chelation therapy 3. Determine adverse events whether drug or non drug related
This is a Phase 1/2, open label, safety, and efficacy study of the administration of LentiGlobin BB305 Drug Product to participants with either transfusion dependent beta-thalassemia (TDT) or sickle cell disease (SCD).
Allo-hematopoietic stem cell transplantation(HSCT) is the only way to cure β-thalassemia major at present. To expand donor pool,we developed a haplo-identical HSCT (Hi-HSCT) platform. But in prior Hi-HSCT using high dose post-transplant Cyclophosphamide in patients with leukemia, cytopenia post-transplant often developed, which was considered as a symptom of GVHD. Therefore, the investigators add unrelated umbilical cord blood (UCB) to the Hi-HSCT. It has reported that, as third-party cells, UCB will reduce GVHD.The purpose of this study is to determine whether unrelated UCB following Hi-HSCT can improve outcomes of Hi-HSCT in patients with β-thalassemia major.
Background: - Some sickle cell disease or beta-thalassemia can be cured with transplant. Researchers want to test a variation of transplant that uses low dose radiation and a combination of immunosuppressive drugs. They want to know if it helps a body to better accept donor stem cells. Objectives: - To see if low dose radiation (300 rads), oral cyclophosphamide, pentostatin, and sirolimus help a body to better accept donor stem cells. Eligibility: - People 4 and older with beta-thalassemia or sickle cell disease that can be cured with transplant, and their donors. Design: - Participants and donors will be screened with medical history, physical exam, blood test, tissue and blood typing, and bone marrow sampling. They will visit a social worker. - Donors: - may receive an intravenous (IV) tube in their groin vein. - will receive a drug injection daily for 5 or 6 days to move the blood stem cells from the bone marrow into general blood circulation. - will undergo apheresis: an IV is put into a vein in each arm. Blood is taken from one arm, a machine removes the white blood cells that contain blood stem cells, and the rest is returned through the other arm. - Participants: - may undergo red cell exchange procedure. - will remain in the hospital for about 30 days. - will receive a large IV line that can stay in their body from transplant through recovery. - will receive a dose of radiation, and transplant related drugs by mouth or IV. - will receive blood stem cells over 8 hours by IV. - will take neuropsychological tests and may complete questionnaires throughout the transplant process. - must stay near NIH for 4 months. They will visit the outpatient clinic weekly. - will have 5 follow-up visits for 3 years after transplant, then annually.
Cardiac failure is the major cause of death in patients with thalassemia and chronic blood transfusion-related iron overload. The treatment of thalassemia has been revolutionized over the past decade with the implementation of cardiac MRI based assessment of iron overload. This has enabled detection of cardiac iron overload prior to symptomatic heart failure and now allows for timely therapy which has resulted in a substantial decrease in mortality. However, currently implemented MR imaging techniques assess for iron content only and not for iron related diffuse fibrosis which play a role in iron related heart failure. Histopathologic studies indicate that patients with iron overload have diffuse interstitial fibrosis. Quantitative MR techniques have shown that patients with various cardiomyopathies demonstrate diffuse myocardial fibrosis and that these changes correlate with changes in cardiac function. The investigators propose that quantitative cardiac MRI for assessment of diffuse myocardial fibrosis can further improve our ability to detect early damage to the myocardium and prevent morbidity and mortality from cardiac iron overload. Detection of fibrosis in patients with thalassemia may allow for earlier identification of cardiomyopathy when compared to other techniques in clinical use including T2* analysis. Identification of fibrosis could affect patient management as it would allow for tailoring of iron chelation therapy and may lead to better understanding of the disease processes contributing to heart failure and arrhythmia in these patients.