20 Clinical Trials for Various Conditions
The primary goal of this Phase I/II study is to assess the immune response and safety of recombinant human CD40 ligand (rhuCD40L) in patients with X-linked hyper IgM syndrome (XHIM). XHIM is a rare genetic disease caused by mutations in the gene encoding CD40 ligand. Individuals with this syndrome fail to make gamma immune globulin, frequently suffer from opportunistic infections, and are at an increased risk of developing cancer. Despite treatment with gamma globulin replacement therapy, the expected survival of patients with XHIM is less than 20 percent by the age of 25. In a mouse model of this syndrome, treatment with man-made CD40 ligand protein protected the mouse from opportunistic infections, restored the mouse's ability to make gamma globulin, and improved survival. We want to determine if a similar approach can work in humans with XHIM. The study will be conducted at the Clinical Center of the National Institutes of Health in Bethesda, Maryland. For most patients, rhuCD40L will be administered by injection under the skin over a period of six months and follow-up exams are required at 2-month intervals for an additional 6 months. During the study, patients will be maintained on intravenous gamma globulin, antibiotics to protect against opportunistic infection, and, if needed, growth factors to control neutropenia. The immune response to rhuCD40Lwill be measured by routine methods such as measuring a patient's ability to synthesize gamma globulin when challenged with immunizations to keyhole limpet hemocyanin (KLH) and Bacteriophage Phi-X 174 (Phi-X 174). Our long-term goal is to define a therapeutic regimen that will provide effective immunological reconstitution to patients with XHIM and improve their life expectancy.
Background: X-linked Hyper IgM (HIGM) syndrome is caused by a mutation in the CD40L gene. People with this disease have white blood cells that do not work properly. These people are at risk of severe infections and autoimmune diseases. Stem cell transplant can cure this disease. However, transplanting stem cells donated by other people can have serious complications. Another approach is gene therapy; this treatment repairs the mutation in a person's own stem cells by base editing. Researchers want to know if these base-edited stem cells can help people with CD40L-HIGM syndrome. Objective: To test base-edited stem cell transplant in 1 person with CD40L-HIGM syndrome. Eligibility: A male with CD40L-HIGM syndrome. Design: Participant will be screened. Tests will include medically indicated imaging scans, blood tests, and a sample of tissue and fluid (biopsy) may be taken from the bone marrow. Participant may undergo apheresis to collect stem cells. The collected stem cells will undergo base editing to repair the mutation. For treatment, participant will be admitted to the hospital for 5 weeks or more. For 2 weeks he will receive drugs to prepare his body for receiving the stem cells. After receiving the edited stem cells, he will remain in the hospital until his cell counts recover. Participant will have follow-up visits every few months in the first 2 years after treatment. The bone marrow biopsy will be repeated after 2 years. Long-term visits will continue annually for 15 years.
This study investigates gene abnormalities in Primary Immune Deficiency(PID) with a goal of improving the diagnosis and treatment of patients. The specific disorders include: 1. X linked hyper IgM Syndrome which is caused by an abnormality in the CD40L gene. 2. NEMO associated immune deficiency which is caused by an abnormality in a gene called NEMO. 3. Common variable immunodeficiency (CVID) which has an unknown genetic basis. 4. Other disorders of immunoglobulin production. This study will: 1. Better characterize the clinical features of CD40 L deficiency and NEMO associated immune deficiency and other related primary immune deficiency syndromes. 2. Determine the frequency of CD40 L and Nemo abnormalities. 3. Determine whether particular abnormalities in these genes are associated with more of less severe illness or with specific symptoms. 4. Explore the basic mechanism by which these altered genes cause immune dysfunction. 5. Identify other genes causing low immune globulin levels and related primary immune deficient states.
Background: Pyrimidine and purine metabolism disorders (DPPMs) affect how the body metabolizes chemicals called pyrimidines and purines. DPPMs can cause dysfunctions throughout the body, especially in the brain, blood, kidneys, and immune system. People with DPPMs might have no symptoms, mild symptoms, or they may have severe, chronic symptoms, that can be fatal. DPPMs are not well understood, and researchers want to learn more about what causes them and how to treat them. Objective: To learn more about factors that affect DPPMs by comparing test results from affected, uaffected family members, and healthy people. Eligibility: Three types of participants are needed: people aged 1 month and older with DPPMs; their family members who do not have DPPMs; and healthy volunteers. Design: Participants with DPPMs will come to the clinic once a year; some may be asked to come more often. At each visit, all affected participants will have a physical exam and give samples of blood, urine, saliva, and stool. Depending on their symptoms, they may also have other procedures, such as: Swabs of their skin and inside the mouth. Tests of their heart, kidney, brain, and nerve function. Questionnaires about what they eat. Dental exams, and exams of their hearing and vision. Tests of their learning ability. Monitoring of their physical activity. Imaging scans. Photographs of their face and body. These tests may be spread over up to 7 days. Affected participants may remain in the study indefinitely if they wish to. Healthy volunteers and family members will have 1 study visit. They will have a physical exam and may be asked to give blood, urine, saliva, and stool samples.
The primary objective is to demonstrate the bioequivalence of Gammaplex® 10 intravenous immunoglobulin (IGIV) and Gammaplex® 5% IGIV with respect to area under the curve within a 28-day dosing interval (AUC0-28) in a cohort of adult subjects. The secondary objectives are to demonstrate the bioequivalence of Gammaplex® 10 IGIV and Gammaplex® 5% IGIV with respect to area under the curve within a 21-day dosing interval (AUC0-21) in adult subjects; to assess the pharmacokinetics of Gammaplex 10 IGIV and Gammaplex 5% IGIV including Immunoglobulin G (IgG) trough levels and to investigate the safety and tolerability of Gammaplex 10 IGIV and Gammaplex 5% IGIV in adults subjects; to assess the pharmacokinetics of Gammaplex 10 IGIV including IgG trough levels and to investigate the safety and tolerability of Gammaplex 10 IGIV in pediatric subjects.
This is a standard of care treatment guideline for allogeneic hematopoetic stem cell transplant (HSCT) in patients with primary immune deficiencies.
The main objective is to determine the efficacy of Gammaplex by measuring the number of serious acute bacterial infections during treatment with Gammaplex over a 12 month period. The secondary objectives are to assess the safety and tolerability of Gammaplex and to compare the data collected from adult subjects with PID from the GMX01 study
OBJECTIVES: I. Provide curative immunoreconstituting allogeneic bone marrow transplantation for patients with primary immunodeficiencies. II. Determine relevant outcomes of this treatment in these patients including quality of survival, extent of morbidity and mortality from complications of the treatment (e.g., graft versus host disease, regimen related toxicities, B- cell lymphoproliferative disease), and completeness of functional immunoreconstitution.
OBJECTIVES: I. Identify the molecular defects responsible for primary immunodeficiency disorders. II. Explore the mutations within each syndrome to better understand the genetics of these disorders. III. Study the function of the Wiskott-Aldrich syndrome proteins (WASP). IV. Design methods to identify carriers and for prenatal diagnosis. V. Explore new avenues for therapy.
The main objective of the study is to determine the pharmacokinetics profile of Subgam-VF. The secondary objectives are to assess the safety of Subgam-VF and refine the dose adjustment coefficient for Subgam-VF needed for subjects switching from prior intravenous immunoglobulin (IGIV) therapy.
This is a clinical trial of bone marrow transplantation for patients with the diagnosis of a genetic disease of blood cells that do not have an HLA-matched sibling donor. Genetic diseases of blood cell include: Red blood cell defects e.g. hemoglobinopathies (sickle cell disease and thalassemia), Blackfan-Diamond anemia and congenital or chronic hemolytic anemias; White blood cells defects/immune deficiencies e.g. chronic granulomatous disease, Wiskott-Aldrich syndrome,Osteopetrosis, Kostmann's syndrome (congenital neutropenia), Hereditary Lymphohistiocytosis (HLH); Platelets defects e.g.Congenital amegakaryocytic thrombocytopenia; Metabolic/storage disorders e.g. leukodystrophies,mucopolysaccharidoses as Hurler disease;Stem cell defects e.g.reticular agenesis, among many other rare similar conditions. The study treatment plan uses a new transplant treatment regimen that aims to try to decrease the acute toxicities and complications associated with the standard treatment plans and to improve outcome The blood stem cells will be derived from either unrelated donor or unrelated umbilical cord blood.
This is a multi-center, open-label study to assess the efficacy and safety of Flebogamma 5% DIF in the pediatric population.
The purpose of this study is to measure the pharmacokinetics, efficacy and safety of Immune Globulin Intravenous (Human) \[IGIV\], 5% Solution Omr-IgG-am™ in patients with primary immunodeficiency diseases.
This study will try to identify mutations in the genes responsible for primary immunodeficiency disorders (inherited diseases of the immune system) and evaluate the course of these diseases in patients over time to learn more about the medical problems they cause. The immune system is composed of various cells (e.g., T and B cells and phagocytes) and other substances (complement system) that protect the body from infections and cancer. Abnormalities in the gene(s) responsible for the function of these components can lead to serious infections and other immune problems. Patients with Wiskott-Aldrich syndrome, adenosine deaminase (ADA) deficiency. Participants will undergo a medical and family history, physical examination, and additional procedures and tests that may include the following: 1. Blood tests for: routine laboratory studies (i.e. cell counts, enzyme levels, electrolytes, etc.); HIV testing; immune response to various substances; genetic testing; and establishment of cell lines to maintain a supply of cells for continued study 2. Urine and saliva tests for biochemical studies 3. Skin tests to assess response to antigens such as the viruses and bacteria responsible for tetanus, candida, tuberculosis, diphtheria, chicken pox, and other diseases. 4. Skin and lymph node biopsies for tissue and DNA studies 5. Chest X-ray, CT scans, or both to look for cancer or various infections. 6. Pulmonary function test to assess lung capacity and a breath test to test for H. pylori infection. 7. Dental, skin and eye examinations. 8. Treatment with intravenous immunoglobulins or antibodies to prevent infections. 9. Apheresis for collecting white blood cells to study cell function. In this procedure, whole blood is collected through a needle placed in an arm vein. The blood circulates through a machine that separates it into its components. The white cells are then removed, and the red cells, platelets and plasma are returned to the body, either through the same needle or through a second needle placed in the other arm. 10. Bone marrow sampling to study the disease. A small amount of marrow from the hipbone is drawn (aspirated) through a needle. The procedure can be done under local anesthesia or light sedation. 11. Placental and umbilical cord blood studies, if cord blood is available, to study stem cells (cells that form blood cells). Information gained from this study may provide a better understanding of primary immunodeficiencies, leading to better diagnosis and treatment. In addition, study participants may receive medical and genetic counseling and may be found eligible for other NIH studies on these diseases.
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 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.
HLH, HLH-related disorders, Chronic Granulomatous (CGD), HIGM1, Immune dysregulation, polyendocrinopathy, enteropathy, and X-linked inheritance (IPEX) and severe LAD-I represent primary immune disorders that are typically fatal without Hematopoietic Cell Transplant (HCT). However, transplant is often complicated by inflammation, infection and other co-morbidities. In addition, these disorders have been shown to be cured with partial chimerism, making them an ideal target for the use of reduced intensity approaches, where a portion of patients may not achieve full donor chimerism, but instead achieve stable mixed chimerism. Reduced-intensity conditioning strategies have demonstrated improved survival with decreased Treatment Related Mortality (TRM) in institutional series for patients with HLH (Cooper et al., 2006; Marsh et al., 2010; Marsh et al., 2011). However, graft loss and unstable chimerism remain challenges. An institutional case series from Cincinnati Children's Hospital demonstrated full or high-level chimerism and improved durable engraftment using intermediate (Day -14) timing alemtuzumab (Marsh et al., 2013b). This study aims to test the efficacy of the Intermediate RIC strategy in a prospective multi-center study including HLH as well as other primary immunodeficiencies where allogeneic transplant with RIC has been shown to be feasible and stable chimerism is curative.
The purpose of this study is to determine whether bilateral orthotopic lung transplantation (BOLT) followed by cadaveric partially-matched hematopoietic stem cell transplantation (HSCT) is safe and effective for patients aged 5-45 years with primary immunodeficiency (PID) and end-stage lung disease.
This study hypothesizes that a reduced intensity immunosuppressive preparative regimen will establish engraftment of donor hematopoietic cells with acceptable early and delayed toxicity in patients with immune function disorders. A regimen that maximizes host immune suppression is expected to reduce graft rejection and optimize donor cell engraftment.
The main objective of this study is to see if GAMMAPLEX is efficacious with respect to Food and Drug Administration (FDA) minimal requirements (no more than 1 serious, acute, bacterial infection per subject per year) in subjects with Primary Immunodeficiency Diseases (PID). The secondary objectives are to assess the safety and tolerability of GAMMAPLEX and to determine if GAMMAPLEX has a pharmacokinetic (PK) profile comparable with that of intact Immunoglobulin G (IgG) in subjects with PID.