50 Clinical Trials for Various Conditions
This study is being done to determine if blood cell transplants, with either bone marrow or cord blood from unrelated donors, are effective in children with severe thalassemia and if this treatment approach has acceptable risks and side effects. This study includes a preparative regimen with Hydroxyurea, Alemtuzumab, Fludarabine, Thiotepa and Melphalan that provides intense host immunosuppression without myeloablation. The primary hypothesis is that this regimen will promote stable engraftment of unrelated donor hematopoietic cells, support normal erythropoiesis, and result in an event free survival of \> 75% of children with thalassemia major.
This study will evaluate the safety and effectiveness of 5-azacytidine and phenylbutyrate for treating thalassemia major. Patients with this disease have abnormal production of hemoglobin (the oxygen-carrying protein in red blood cells), which leads to red blood cell destruction. As a result, patients require frequent red cell transfusions over many years. Because of these transfusions, however, excess iron is deposited in various body organs-such as the heart, liver, thyroid gland and, in men, the testes-impairing their function. Fetal hemoglobin-a type of hemoglobin that is produced during fetal and infant life-can substitute for adult hemoglobin and increase the levels of red cells in the body. After infancy, however, this type of hemoglobin is no longer produced in large quantities. 5-azacytidine can increase fetal hemoglobin levels, but this drug can damage DNA, which in turn can increase the risk of cancer. This study will try to lessen the harmful effects of 5-azacytidine by using only one or two doses of it, followed by long-term therapy with phenylbutyrate, a drug that may be as effective as 5-azacytidine with less harmful side effects. Patients 18 years of age and older with severe thalassemia major may be eligible for this study. Before beginning treatment, candidates will have a medical history and physical examination, blood tests, chest X-ray, electrocardiogram (EKG), bone marrow biopsy (removal of a small sample of bone marrow from the hip for microscopic examination) and whole-body magnetic resonance imaging (MRI). For the biopsy, the area of the hip is anesthetized and a special needle is inserted to draw bone marrow from the hipbone. For the MRI scan, a strong magnetic field is used to produce images that will identify sites where the body is making red blood cells. During this procedure, the patient lies on a table in a narrow cylinder containing a magnetic field. Earplugs are placed in the ears to muffle the loud thumping sounds the machine makes when the magnetic fields are being switched. An intravenous (IV) catheter (flexible tube inserted into a vein) is placed in a large vein of the patient's neck, chest or arm for infusion of 5-azacytidine at a constant rate over 4 days. Patients who do not respond to this first dose of 5-azacytidine will be given the drug again after about 50 days. If they do not respond to the second dose, alternate treatments will have to be considered. Patients who respond to 5-azacytidine will begin taking phenylbutyrate on the 14th day after 5-azacytidine was started. They will take about 10 large pills 3 times a day, continuing for as long as the treatment is beneficial. All patients will be hospitalized for at least 6 days starting with the beginning of 5-azacytidine therapy. Those who are well enough may then be discharged and continue treatment as an outpatient. Patients will be monitored with blood tests daily for 2 weeks and then will be seen weekly for about another 5 weeks. Bone marrow biopsies will be repeated 6 days after treatment begins and again at 2 weeks and 7 weeks. MRI will be repeated 7 weeks after treatment begins. After 7 weeks, patients will be seen at 3-month intervals. Bone marrow biopsies will be done every 6 months for the first 3 years after treatment. Patients will have red cell transfusions as needed and chelation therapy to remove excess iron.
The investigators aims to evaluate the safety of in utero hematopoietic stem cell transplantation in fetuses with alpha-thalassemia major performed at the time of in utero transfusion of red blood cells.
Beta thalassemia (β-thalassemia) is the most common genetic disease worldwide. Individuals with thalassemia are born with a defect in hemoglobin. Hemoglobin is a protein in red blood cells that carries oxygen to vital organs such as the brain, heart, lungs and kidneys. Thalassemia major is a hereditary anemia characterized by little or no ß-globin production, which results in hemolysis (breakdown or destruction of red blood cells) due to the formation of unstable alpha-globin tetramers and ineffective erythropoiesis which is uniformly fatal in the absence of regular transfusions. Although improvements in conservative treatment have improved the prognosis of thalassemia considerably disease and transfusion related complications in affected patients progress over time, causing severe morbidity and shortened life expectancy. Substantial lifelong health care expenses are also involved, often a financial burden for families and unsustainable in most developing countries. The hypothesis is that patients who had beta thalassemia who have undergone a hematopoietic stem cell transplant (HSCT) and are \>1 year post-HSCT will have less long term comorbidities and a higher quality of life (QOL) as compared to those with beta thalassemia who are maintained on supportive care. In order to assess quality of life, a quality of life questionnaire will be asked. Extraction of data from the patient's medical record will also be used to determine any comorbidities that have occurred after either a HSCT or supportive care therapy.
This is a non-randomized, open label, multi-site, single-dose, phase 1/2 study in up to 18 participants (including at least 3 adolescents between 12 and 17 years of age, inclusive) with β-thalassemia major. The study will evaluate the safety and efficacy of autologous hematopoietic stem cell transplantation (HSCT) using LentiGlobin BB305 Drug Product \[autologous CD34+ hematopoietic stem cells transduced with LentiGlobin BB305 lentiviral vector encoding the human βA-T87Q-globin gene\].
The purpose of this study is to collect peripheral blood and bone marrow aspirate samples from thalassemia patients in Tehran, in a collaborative effort to develop an erythroid lineage specific chimerism assay applicable to patients with thalassemia. Development of such an assay would be useful both for identification of the exact mutation causing the disease, as well as for providing a direct method to measure and monitor the kinetics of donor erythropoiesis in this patient population following transplant.
This study is a multicenter, open-label, two-period crossover design that evaluates the safety, tolerability, pharmacokinetics and preliminary evidence of iron chelating activity of DST-0509 as compared to Jadenu and Exjade in transfusion-dependent thalassemia patients with transfusional iron overload, requiring iron chelation therapy and demonstrating an inadequate response to Jadenu or Exjade for greater than 3 months duration. Up to 36 patients will be evaluated (18 in each treatment arm), however, the balanced randomization may enroll fewer patients based on recruitment status.
The improved long-term survival of thalassemia major (TM) patients has resulted in increased focus on the ability to preserve fertility. While the association of iron toxicity with vital organ dysfunction, heart and liver, has been extensively investigated, the correlation of reproductive capacity and extent of iron overload is not well understood. Despite remarkable progress in methodology for prediction of reproductive status and intervention for preserving fertility, implementation in thalassemia is lacking. The investigators hypothesize that iron toxicity to the anterior pituitary occurring in the process of transfusional iron loading is directly associated with a decline in gonadal function. The investigators expect pituitary MRI measurements of iron deposition as well as markers of oxidative damage to correlate with the functional studies of pituitary-gonadal axis performed in this study. This cross sectional study will examine the relation of pituitary iron deposition and pituitary volume; serum iron and oxidative stress measures, liver iron concentration (LIC), cardiac iron and chelation adequacy with pituitary and gonadal reproductive hormone levels (and spermatogenesis in adult male patients), in order to better define the association of iron burden and chelation patterns with fertility potential, in thalassemia patients with iron overload. The study will assess whether the current chelation treatment regimens, in particular during the pubertal developmental age, are adequate for preserving fertility and could lead to improved chelation routines for preventing the high prevalence of compromised fertility. In addition, by utilizing state-of-the-art markers for fertility status, findings from this study may improve current methods for screening for hypogonadism and reproductive potential and allow earlier intervention. The investigators propose to examine 26-30 patients, 12 years and older, with measures of fertility potential, and correlate them to their current iron burden parameters and to the cumulative iron effect as indicated by past iron overload patterns and chelation history.
We hypothesize that the combination treatment with deferasirox and deferiprone will be well tolerated and will result in significant improvement in cardiac and liver iron levels.
The purpose of this pilot study is to determine the effect of various doses of vitamin D supplementation on vitamin D stores and calcium excretion in the urine in subjects with Thalassemia Major (TM). Subjects with TM are routinely placed on vitamin D supplements because they frequently have osteoporosis (a condition in which bone tissue thins and loses density and strength) and low vitamin D stores. The amount of vitamin D supplementation that is required to raise vitamin D stores in optimal levels is not known in TM, and will be determined in this study. Finally, a recent study in TM has linked blood vitamin D levels to urine calcium excretion, which is a risk factor for kidney stones. Therefore, we want to determine changes in calcium excretion with various vitamin D doses and with increasing vitamin D stores. We plan to test 3 doses of vitamin D for 3 months in children and adults with TM. Changes in vitamin D blood levels and urinary calcium will be determined. The results of this pilot study will be used in future studies that will examine the effect of various doses of vitamin D supplementation in the treatment of osteoporosis in TM.
Betathalassemia major is a disease of the blood and bone marrow. You were born with it and it has made you unable to make normal hemoglobin and red cells. You have been receiving red blood cell transfusions all your life. These transfusions do not cure your disease. The problem with transfusions is that they contain a lot of iron. With time iron builds up in your body and will eventually hurt some of your organs . Because of this buildup of iron , you are taking medicine that helps your body get rid of the extra iron. Today, the only other treatment is bone marrow or stem cell transplant. It can only be done when a matched donor is available. This is most often a brother, sister, or parent. Bone marrow transplant may cure betathalassemia major. If you have a transplant and it is successful, you will no longer have the disease. Without a matched sibling or parent, the standard treatment is to keep having transfusions. In the near future, we will be testing a new treatment for making normal hemoglobin and normal red blood cells. We have recreated the healthy hemoglobin gene in a test tube. We are able to use it and put it back into cells. This is called gene therapy. We have been able to put this gene into the stem cells of mice with thalassemia. These mice were cured. We now plan to take that gene and put it into stem cells from people who have betathalassemia major. We will then inject those stem cells back into that person's blood. In general, we can obtain more stem cells from the blood of a person than from the bone marrow . In order to do so, we must give that person a blood growth factor. The growth factor stimulates the bone marrow to make more stem cells. That growth factor is called granulocyte colony stimulating factor (GCSF), or Filgrastim. The purpose of this trial is to find out if the drug GCSF has any side effects on you, and if you will make more stem cells in response to it. This trial is not a gene therapy trial. This trial will not help your thalassemia.
The purpose of this study is to evaluate the safety, tolerability, and efficacy of treatment with EDIT-301 in adult participants with Transfusion Dependent beta Thalassemia
This is an international prospective registry of patients with Alpha thalassemia to understand the natural history of the disease and the outcomes of fetal therapies, with the overall goal of improving the prenatal management of patients with Alpha thalassemia.
This is a single arm pilot study of peripheral stem cell transplantation (PSCT) with ex vivo t-cell receptor alpha beta+(TCRαβ+) T cell and cluster of differentiation 19+ beta (CD19+ B) cell depletion of unrelated donor (URD) grafts using the CliniMACS device in patients with sickle cell disease (SCD) and beta thalassemia major (BTM).
The purpose of this study is to evaluate what effect, if any, mismatched unrelated volunteer donor and/or haploidentical related donor stem cell transplant may have on severe sickle cell disease and other transfusion dependent anemias. By using mismatched unrelated volunteer donor and/or haploidentical related donor stem cells, this study will increase the number of patients who can undergo a stem cell transplant for their specified disease. Additionally, using a T-cell depleted approach should reduce the incidence of graft-versus-host disease which would otherwise be increased in a mismatched transplant setting.
This study will evaluate the use of reduced intensity conditioning regimen in patients with high risk hemoglobinopathy Sickle Cell and B-Thalassemia Major in combination with standard immunosuppressive medications, followed by a routine stem cell transplant in order to assess whether or not it is as effective as myeloablative high dose chemotherapy and transplant.
This is a single arm, phase I study to assess the tolerability of abatacept when combined with cyclosporine and mycophenolate mofetil as graft versus host disease prophylaxis in children undergoing unrelated hematopoietic stem cell transplant for serious non-malignant diseases as well as to assess the immunological effects of abatacept. Participants will be followed for 2 years.
The proposed research project will continue the application and development of a new method (biomagnetic susceptometry) that measures magnetic fields to determine how much iron is in the liver. The amount of iron in the liver is the best indicator of the amount of iron in the whole body. Measuring the amount of iron in the body is important because either too much (iron overload) or too little iron (iron deficiency) can be harmful. At present, the most reliable way to measure the amount of iron in the liver is to remove a sample of the liver by biopsy, either by surgery or by using a needle which pierces the skin and liver. Iron stored in the liver can be magnetized to a small degree when placed in a magnetic field. In patients with iron overload, the investigators previous studies have shown that magnetic measurements of liver iron in patients with iron overload are quantitatively equivalent to biochemical determinations on tissue obtained by biopsy. In the past the investigators have developed a device to measure the amount of magnetization, which was called a SQUID (Superconducting QUantum Interference Device) susceptometer. This device was validated and in use for over 20 years. The safety, ease, rapidity and comfort of magnetic measurements make frequent, serial studies technically feasible and practically acceptable to patients. The investigators have now developed a new susceptometer, which uses very similar technology to the SQUID, but the investigators believe is more accurate and precise. This study aims to validate this new instrument. The investigators will do prospective, serial studies of the diagnosis and management of patients with iron overload, including thalassemia major (Cooley's anemia), sickle cell disease, aplastic anemia, myelodysplasia, hereditary hemochromatosis, and other disorders. Funding Source - FDA OOPD.
This purpose of this study is to understand the differences between people who have a good response to deferasirox (exjade) compared to people who have a poor response to this medication when used for transfusion-dependent iron overload. The hypothesis is that patients with poor responses have physiologic barriers to deferasirox that may include absorption, pharmacokinetics of drug metabolism, hepatic clearance and/or genetic factors.
The purpose of this study is to find out if using a lower dose of chemotherapy before stem cell transplantation can cure patients of sickle cell anemia or thalassemia while causing fewer severe side effects than conventional high dose chemotherapy with transplantation.
OBJECTIVES: I. Determine the efficacy of bone marrow transplantation using matched related donors in patients with nonmalignant hematologic disorders. II. Determine the quality of life, absence of adverse effects (e.g., graft versus host disease and B cell lymphoproliferative disease), and completeness of recovery of their underlying condition in these patients with this treatment regimen.
OBJECTIVES: I. Ascertain whether stem cell transplantation (SCT) is an effective method by which missing or dysfunctional enzymes can be replaced in patients with various inborn errors of metabolism. II. Determine whether clinical manifestations of the specific disease may be arrested or reversed by this treatment.
The purpose of this study is to evaluate the long-term safety and efficacy of EDIT-301 in participants with severe sickle cell disease (SCD) or transfusion-dependent β-thalassemia (TDT) who have received EDIT-301.
This is a data collection study that will examine the general diagnostic and treatment data associated with the reduced-intensity chemotherapy-based regimen paired with simple alemtuzumab dosing strata designed to prevented graft failure and to aid in immune reconstitution following hematopoietic stem cell transplantation.
The overall goal of this research is to help develop a new magnetic resonance (MR) method, Quantitative Susceptibility Mapping (QSM), to improve the measurement of liver iron concentrations without the need for a liver biopsy. Measurement of liver iron is important to diagnose and treat patients who have too much iron in their bodies (iron overload). Liver iron measurements by current MRI methods (R2 and R2\*) can be inaccurate because of the effects of fat, fibrosis and other abnormalities. QSM should not be affected by these factors and should be free of these errors. In this study, MRI measurements (QSM, R2 and R2\*) of iron in patients before liver transplant will be compared with chemical analysis of iron in liver explants (livers removed from patients undergoing liver transplant). The liver explants would otherwise be discarded. Investigators expect that this study will show that the new MRI method, QSM, is superior to the current MRI methods, R2 and R2\*.
This is a single-arm, multi-site, single-dose, Phase 1/2 study to assess ST-400 in 6 subjects with transfusion-dependent β-thalassemia (TDT) who are ≥18 and ≤40 years of age. ST-400 is a type of investigational therapy that consists of gene edited cells. ST-400 is composed of the patient's own blood stem cells which are genetically modified in the laboratory using Sangamo's zinc finger nuclease (ZFN) technology to disrupt a precise and specific sequence of the enhancer of the BCL11A gene (which normally suppresses fetal hemoglobin production in erythrocytes). This process is intended to boost fetal hemoglobin (HbF), which can substitute for reduced or absent adult (defective) hemoglobin. ST-400 is then infused back into the patient after receiving conditioning chemotherapy to make room for the new cells in the bone marrow, with the aim of producing new erythrocytes with increased amounts of HbF. The primary objective is to understand safety and tolerability of ST-400, and secondary objectives are to assess the effects on HbF levels and transfusion requirements.
The objective of this study is to evaluate the efficacy of using a reduced-intensity condition (RIC) regimen with umbilical cord blood transplant (UCBT), double cord UCBT, matched unrelated donor (MUD) bone marrow transplant (BMT) or peripheral blood stem cell transplant (PBSCT) in patients with non-malignant disorders that are amenable to treatment with hematopoietic stem cell transplant (HSCT). After transplant, subjects will be followed for late effects and for ongoing graft success.
OBJECTIVES: I. Compare the efficacy of local care alone vs local care plus arginine butyrate in terms of healing rate in patients with refractory sickle cell ulcers. II. Determine the effect of arginine butyrate therapy on tissue factors related to promotion or inhibition of wound healing in these patients. III. Determine whether the regimen used in this study is appropriate for testing in pivotal trials.
This is a single-dose, open-label study in participants with transfusion-dependent β-thalassemia (TDT) or severe sickle cell disease (SCD). The study will evaluate the safety and efficacy of autologous CRISPR-Cas9 modified CD34+ human hematopoietic stem and progenitor cells (hHSPCs) using CTX001.
Patients have severe beta-thalassemia or one of the thalassemia variants. Thalassemia is a hereditary disease in which the bone marrow produces abnormal red blood cells that have a shorter life span than normal red blood cells. Because of that, the patient has chronically low red blood cell numbers (anemia) and need regular blood transfusions to help the patient feel better and to help prevent damage to important organs such as the heart. The following treatments are currently available to patients: lifelong blood transfusions and drugs that help remove iron from the body, and long-term antibiotics to prevent infections. These treatments are difficult for patients to take, and do not stop the effects of the disease. Currently, the only treatment that may cure thalassemia is bone marrow or blood stem cell transplantation. Special blood or bone marrow cells from a healthy person might allow the bone marrow to create healthy cells, which will replace the abnormal red blood cells of thalassemia. There is a lot of experience using special blood or bone marrow cells from a healthy brother or sister who is the same HLA (immune) type. For patients who do not have such a donor in the family, an unrelated volunteer donor can be used. It is important for the patient to realize that this kind of transplant can have more problems than a transplant from a brother or sister. Because we do not know the long-term effects of this treatment and because this type of transplant has not been used often for people with thalassemia, this is a research study. We hope, but cannot promise, that the transplanted marrow/stem cells will produce healthy cells and the patient will no longer have severe thalassemia.