View clinical trials related to Deficiency Diseases.
Filter by:This is a multicenter, randomized trial to compare the safety and efficacy of two dosing frequencies of Cerezyme® in patients with Gaucher disease who are currently being treated with Cerezyme®. Approximately 90 patients will be randomized in a 2:1 (q4 : q2) ratio to one of two treatment arms at up to 26 study centers worldwide. Patients will continue to receive the same total 4-week dose that they were receiving prior to study enrollment, however, they will be randomized to receive either their total 4-week dose in two infusions, one infusion every 2 weeks or their total 4-week dose in one infusion every 4 weeks. The randomization scheme will ensure a 2:1 balance between the every 4-week versus every 2-week infusion groups, respectively.
Helicobacter pylori is recognized as a major gastrointestinal pathogen in developing countries. This microorganism infects up to 60% of children less than five years in those countries and is strongly associated with chronic gastritis and peptic ulcer disease in children and adults. The progression of gastritis to atrophy often leads to decreased gastric acid output, which is a well-known risk factor for anemia. Gastric acid is essential for increasing the bioavailability and absorption of non-heme dietary iron, the most important source of iron in developing countries. Numerous reports suggest that iron malabsorption secondary to low gastric acid output is a problem in developing world countries. It has been further observed that iron deficiency anemia is resistant to iron therapy particularly in these countries. In a recently completed study we observed an association of anaemia with H. pylori infection. We hypothesize that the poor bioavailability of iron in these countries could be related to H. pylori -induced low gastric acid output and we propose to investigate the role of H. pylori infection as a cause of anemia and treatment failure of iron supplementation in Bangladesh. A prospective, randomized, double-blind, placebo-controlled field trial is proposed among four groups ( 65 each) of H. Pylori infected children of 2-5 years of age with iron deficiency anemia. The children will be assigned to one of the four therapies: antibiotics alone (for H. Pylori eradication), antibiotic plus iron therapy, iron therapy alone, or placebo. Hemoglobin concentration, serum ferritin concentration, and transferrin receptor will be measured before and at 1 and 3 month after the intervention. We also propose a complementary study in an additional 20 children with H. Pylori infection and iron deficiency anemia to assess iron absorption with application of double stable isotopes. The change in hematological parameters will also be compared among the groups before and after the therapy. The results of this study are expected to have implications in the prevention and treatment of iron deficiency anemia in developing countries.
Pompe disease (also known as glycogen storage disease Type II) is caused by a deficiency of a critical enzyme in the body called acid alpha-glucosidase (GAA). Normally, GAA is used by the body's cells to break down glycogen (a stored form of sugar) within specialized structures called lysosomes. In patients with Pompe disease, an excessive amount of glycogen accumulates and is stored in various tissues, especially heart and skeletal muscle, which prevents their normal function. The overall objective is to evaluate the safety and efficacy of rhGAA in patients with advanced Late-onset Pompe disease.
Pompe disease (also known as glycogen storage disease Type II) is caused by a deficiency of a critical enzyme in the body called acid alpha-glucosidase (GAA). Normally, GAA is used by the body's cells to break down glycogen (a stored form of sugar) within specialized structures called lysosomes. In patients with Pompe disease, an excessive amount of glycogen accumulates and is stored in various tissues, especially heart and skeletal muscle, which prevents their normal function. The overall objective is to evaluate the safety, pharmacokinetics (PK) and efficacy of Myozyme treatment.
This is a multi-institution, single arm, non-randomized pilot study coordinated by the Pediatric Blood and Marrow Transplant Consortium. Eligible patients will have severe combined immunodeficiency syndrome (SCID) or severe T-cell immunodeficiency disorder. Patients with these disorders do not have properly functioning immune systems. Without treatment, these disorders result in early childhood death. The standard treatment used for these diseases is to give the patient a stem cell transplant from a matched donor. The donor cells can be from a family member, an unrelated marrow donor or umbilical cord blood. The donor source will impact on transplant risks and approaches to the preparative regimen. There have been many different preparative regimens used for patients with SCIDS or severe T-cell immunodeficiency syndromes. Some patients have gotten no preparative regimen, while others have gotten only antithymocyte globulin (ATG; immune proteins made in horses that, when given, will kill lymphocytes). Still other patients have gotten conventional chemotherapy. In children treated with nothing or ATG alone, there is an increased risk of graft failure or only partial engraftment. When this happens, patients need life-long therapy with immunoglobulins to support the immune system. Children treated with chemotherapy generally have full immune recovery, but also may have major side effects from the chemotherapy. The side effects include infection, organ failure and infertility. This protocol, in combination with a parallel study with a separate preparative regimen, will attempt to answer the question of which patients with primary immunodeficiencies need a preparative regimen and what intensity is needed. Patients will be enrolled according to disease type and donor source. The purpose of this study is to see how much chemotherapy is actually needed for the transplant to work. To be able to do this and still make the transplant work, the drugs used to temporarily weaken the immune system will be strengthened. In groups, patients will be treated with lowering doses of the busulfan to find the lowest dose of this drug that is needed to get full immune recovery. The investigators hope this regimen will result in complete immune system recovery while limiting the side effects of chemotherapy. A second purpose of this study is to track the recovery of different parts of the immune system. The investigators also want to identify whether the recovery is coming from donor stem cells or from the patient. The patient will be admitted to the hospital to have the transplant and is expected to stay for up to 4 to 6 weeks. The preparative regimen will be made up of busulfan, fludarabine and antithymocyte globulin (ATG). After the preparative regimen, the cells from the donor will be given. To try and keep the patient's body from rejecting the donor cells and the donor cells from attacking the patient's body (graft-versus-host disease, or GVHD), cyclosporine will be given. The investigators will draw an extra 2 - 4 teaspoons of blood at specified time points to test for immune recovery and donor cell chimerism (the portion of the blood that belongs to the donor). Standard bone marrow transplant (BMT) clinical care will be provided with respect to pretransplant evaluation, peritransplant support, and posttransplant follow-up.
This is a phase 3 clinical investigation. Patients who meet the eligibility criteria and provide signed informed consent will be randomized to receive one of two levels of Ferrlecit or oral iron in a 1:1:1 ratio.
Mother with severe Iodine deficiency are more likely to have neonates with further poor mental development . In order to select population which could benefit from iodine supplementation, ioduria has been tested but cannot be routinely practised. Strong background data suggest that iodine status could be antenatally correlated with foetal thyroid volume. The aim of that study is to examine correlation between these two parameter in a population of 130 healthy pregnant women.
Pompe disease (also known as glycogen storage disease Type II) is caused by a deficiency of a critical enzyme in the body called acid alpha-glucosidase (GAA). Normally, GAA is used by the body's cells to break down glycogen (a stored form of sugar) within specialized structures called lysosomes. In patients with Pompe disease, an excessive amount of glycogen accumulates and is stored in various tissues, especially heart and skeletal muscle, which prevents their normal function. The overall objective is to evaluate the safety, efficacy, and pharmacokinetics (PK) of alglucosidase alfa treatment in patients with late-onset Pompe disease as compared to placebo.
Glycogen Storage Disease Type II ("GSD-II"; also known as Pompe disease) is caused by a deficiency of a critical enzyme in the body called acid alpha-glucosidase (GAA). Normally, GAA is used by the body's cells to break down glycogen (a stored form of sugar) within specialized structures called lysosomes. In patients with GSD-II, an excessive amount of glycogen accumulates and is stored in various tissues, especially heart and skeletal muscle, which prevents their normal function. This study is being conducted to evaluate the safety and effectiveness of recombinant human acid alpha-glucosidase (rhGAA) as a potential enzyme replacement therapy for GSD-II. Patients diagnosed with infantile-onset GSD-II who are greater than 6 months old, but less than or equal to 36 months old will be studied.
GSD-II (also known as Pompe disease) is caused by a deficiency of a critical enzyme in the body called acid alpha-glucosidase (GAA). Normally, GAA is used by the body's cells to break down glycogen (a stored form of sugar) within specialized structures called lysosomes. In patients with GSD-II, an excessive amount of glycogen accumulates and is stored in various tissues, especially heart and skeletal muscle, which prevents their normal function. This study is being conducted to evaluate the safety, pharmacokinetics, pharmacodynamics and efficacy of recombinant human acid alpha-glucosidase (rhGAA) as a potential enzyme replacement therapy for a pair of siblings with GSD-II. To be eligible for this study, a patient must have a confirmed diagnosis of GSD-II and have a sister or brother who also has a confirmed diagnosis of GSD-II.