View clinical trials related to Sickle Cell Disease.
Filter by:Stroke is a frequent complication of sickle cell disease (SCD), with varying levels of central nervous system (CNS) involvement. The summation of several ischemic events, even when silent, can lead to devastating consequences, from reduced academic performance to physical dependence. Despite knowledge that brain flow velocities evaluated by Doppler ultrasound identify pediatric SCD patients at a greater stroke risk (Adams et al, NEJM 1998; 339:5-11), this method is not able to predict the occurrence of strokes in adults. There is also no consensus on the management of adult patients in relation to primary and secondary prevention. The aim of this study is to evaluate the effects of the administration of Simvastatin on CNS structural and functional vascular changes in 30 adult patients with SCD (SS and Sβ), above 35 years of age, observed through Magnetic Resonance Imaging (MRI). The data on the effect of simvastatin on disease manifestations is quite scarce, however this drug reportedly significantly reduces plasma concentrations of adhesion molecules and inflammatory markers, such as E-selectin, VEGF, CRP and IL-6 (Hoppe et al, BJH 2011; 153:655-663; Hoppe et al, BJH 2017;177:620-629). Thus, in addition to the search for early diagnostic markers and risk stratification for primary or recurrent stroke, we will also compare CNS images before and 12 months after the administration of Simvastatin. The drug alter stroke recurrence rates in the general adult population, but their effects on vascular changes in patients with SCD have not yet been adequately elucidated. This is particularly important because these are low cost drugs which present good tolerability, and could be part of the therapeutic arsenal of SCD, even in low income settings. Concomitantly with the CNS evaluation, this study also intends to investigate molecular pathways that may be affected by the drugs. We will evaluate microvesicle release patterns, as well as the content of microRNAs possibly involved in the occurrence of stroke, in addition to metabolomic studies and plasma cytokine profile.
Open Label Extension Study of Voxelotor Clinical Trial Participants with Sickle Cell Disease Who Participated in Voxelotor Clinical Trials
Children with sickle cell disease (SCD) are living longer with the advent of medical advances such as prophylactic penicillin, chronic transfusion, and hydroxyurea. Despite greater longevity in SCD, the period following the transition from pediatric to adult care is critical; youth aged 18-30 years are at high risk for mortality and have high rates of healthcare utilization, leading to high healthcare costs. As such, health care transition (HCT) programs have been created to prepare patients for adult-centered care and subsequently, improve health outcomes. However, very few programs have been evaluated for effectiveness in achieving optimal health outcomes in SCD. This paucity of program evaluation is attributed to a lack of identifiable predictors and outcomes. Researchers at St. Jude Children's Research Hospital want to identify factors and patterns of successful HCT. This information will be used to develop approaches to best evaluate HCT interventions and identify areas of improvement of HCT programming. PRIMARY OBJECTIVE: Describe hospital utilization, treatment adherence, and health-related quality of life in a cohort of patients with sickle cell disease (SCD) who will transfer to adult care during the study period. SECONDARY OBJECTIVE: Examine the associations between various factors and health care transition (HCT) outcomes.
This phase II trial studies how well fludarabine phosphate, cyclophosphamide, total body irradiation, and donor stem cell transplant work in treating patients with blood cancer. Drugs used in chemotherapy, such as fludarabine phosphate and cyclophosphamide, work in different ways to stop the growth of cancer cells, either by killing the cells, by stopping them from dividing, or by stopping them from spreading. Radiation therapy uses high energy x-rays to kill cancer cells and shrink tumors. Giving chemotherapy and total-body irradiation before a donor peripheral blood stem cell transplant helps stop the growth of cells in the bone marrow, including normal blood-forming cells (stem cells) and cancer cells. It may also stop the patient's immune system from rejecting the donor's stem cells. When the healthy stem cells from a donor are infused into the patient they may help the patient's bone marrow make stem cells, red blood cells, white blood cells, and platelets. The donated stem cells may also replace the patient?s immune cells and help destroy any remaining cancer cells.
A promising approach for the treatment of genetic diseases is called gene therapy. Gene therapy is a relatively new field of medicine that uses genetic material (mostly DNA) from the patient to treat his or her own disease. In gene therapy, the investigators introduce new genetic material in order to fix or replace the patient's disease gene, with the goal of curing the disease. The procedure is similar to a bone marrow transplant, in that the patient's malfunctioning blood stem cells are reduced or eliminated using chemotherapy, but it is different because instead of using a different person's (donor) blood stem cells for the transplant, the patient's own blood stem cells are given back after the new genetic material has been introduced into those cells. This approach has the advantage of eliminating any risk of GVHD, reducing the risk of graft rejection, and may also allow less chemotherapy to be utilized for the conditioning portion of the transplant procedure. The method used to introduce the gene into the patient's own blood stem cells is to engineer and use a modified version of a virus (called a 'vector') that efficiently inserts the "correcting" genetic material into the cells. The vector is a specialized biological medicine that has been formulated for use in human beings. The investigators have recently discovered a gene that is very important in the control of fetal hemoglobin expression. Increasing the expression of this gene in sickle cell patients could increase the amount of fetal hemoglobin while simultaneously reducing the amount of sickle hemoglobin in their blood, and therefore potentially cure the condition. In summary, the advantages of a gene therapy approach include: 1) it can be used even if the patient does not have a matched donor available; 2) it may allow a reduction in the amount of chemotherapy required to prepare the patient for the transplant; and 3) it will avoid the strong medicines often required to prevent and treat GVHD and rejection. The goal is to test whether this approach is safe, and whether using gene therapy to change the expression of this particular gene will lead to increased fetal hemoglobin production in people with sickle cell disease.
This is a prospective clinical cohort study that involves a baseline study visit followed by up to 3 annual follow-up study visits for a total follow-up of 36-48 months to evaluate the age- and sex-adjusted rate of change in kidney function, and to identify biomarkers of endothelial function, metabolomic profiles and clinical characteristics for the worsening of kidney function and for a rapid decline in kidney function. "Funding Source - FDA OOPD"
This is a Phase II, single arm, multi-center trial, designed to estimate the efficacy and toxicity of haploidentical bone marrow transplantation (BMT) in patients with sickle cell disease (SCD). Based on their age and entry criteria patients are stratified into two groups: (1) children with severe SCD; and (2) adults with severe SCD.
Blood stem cells can produce red blood cells (which carry oxygen), white blood cells of the immune system (which fight infections) and platelets (which help the blood clot). Patients with sickle cell disease produce abnormal red blood cells. A blood stem cell transplant from a donor is a treatment option for patients with severe sickle cell disease. The donor can be healthy or have the sickle cell trait. The blood stem cell transplant will be given to the patient as an intravenous infusion (IV). The donor blood stem cells will then make normal red blood cells - as well as other types of blood cells - in the patient. When blood cells from two people co-exist in the patient, this is called mixed chimerism. Most children are successfully treated with blood stem cells from a sibling (brother/sister) who completely shares their tissue type (full-matched donor). However, transplant is not an option for patients who (1) have serious medical problems, and/or (2) do not have a full-matched donor. Most patients will have a relative who shares half of their tissue type (e.g. parent, child, and brother/sister) and can be a donor (half-matched or haploidentical donor). Adult patients with severe sickle cell disease were successfully treated with a half-matched transplant in a clinical study. Researchers would like to make half-matched transplant an option for more patients by (1) improving transplant success and (2) reducing transplanted-related complications. This research transplant is being tested in this Pilot study for the first time. It is different from a standard transplant because: 1. Half-matched related donors will be used, and 2. A new combination of drugs (chemotherapy) that does not completely wipe out the bone marrow cells (non-myeloablative treatment) will be used to prepare the patient for transplant, and 3. Most of the donor CD4+ T cells (a type of immune cells) will be removed (depleted) before giving the blood stem cell transplant to the patient to improve transplant outcomes. It is hoped that the research transplant: 1. Will reverse sickle cell disease and improve patient quality of life, 2. Will reduce side effects and help the patient recover faster from the transplant, 3. Help the patient keep the transplant longer and 4. Reduce serious transplant-related complications.
multicentric interventional biomedical research phase II, prospective, non-randomized evaluating a haploidentical marrow transplants after reduced-intensity conditioning and prevention of GvHD based on cyclophosphamide administration post transplantation in patients with severe sickle cell disease.
Background: Peripheral blood stem cell transplantation procedures are used for people with sickle cell disease. Researchers want to improve the success and reduce the complications for these procedures. This might allow more people to have a transplant. Objective: To see if a new transplant regime is effective, safe and well tolerated in people with sickle cell disease. Eligibility: Adults at least 18 years old with sickle cell disease and certain complications. A relative who is a half tissue match. Design: Participants will be screened with medical history, physical exam, and blood tests. Recipients will also have: - Heart, lung, and mental health tests - Chest x-rays - Bone marrow taken from the pelvic bone - Eyes and teeth checked Recipients will have a large central line inserted into a vein for up to 6 months. Donors will have their veins tested and have an IV inserted for 1 day or on rare occasions 2 days. Donors will get a drug to activate bone marrow. It will be injected for about 6 days. Donors will have at least 1 five-hour procedure where bone marrow stem cells will be collected. Blood will be taken from a vein in one arm or in rare cases from a groin vein and put through a machine. Some blood will be saved and the rest will be returned. Stem cells will be taken from the saved blood in a lab and frozen until ready to give to the recipient. Recipients will have: - Stems cells collected and frozen - Hygiene lessons - Bone density scans - Low-dose radiation - Drugs for their immune system - Donor cells infused through their central line - Transfusions After about 30 days, recipients will leave the hospital. They must stay near NIH for 3 months after the transplant and have frequent visits. After returning home, they will have 8 visits over 5 years, then be contacted yearly. ...