View clinical trials related to Anemia, Sickle Cell.
Filter by:The purpose of this study is to determine whether alpha-lipoic acid and acetyl-L-carnitine will lower systemic inflammation in patients with Sickle Cell Disease by reducing oxidative stress, which will result in a decrease in the frequency of vaso-occlusive pain episodes and improve their quality of life.
CD34+ stem cell selection in children, adolescents and young adults receiving partially matched family donor or matched unrelated adult donor allogeneic bone marrow or peripheral blood stem cell transplant will be safe and well tolerated and be associated with a low incidence of serious (Grade III/IV) acute and chronic graft versus host disease (GVHD).
The primary hypothesis of this study is that glutamine supplementation will improve the erythrocyte glutamine/glutamate ratio, a biomarker of oxidative stress, hemolysis and pulmonary hypertension (PH) in sickle cell disease (SCD) and thalassemia (Thal) patients with PH. PH is defined as a tricuspid regurgitant jet velocity (TRV) on Doppler echocardiography > 2.5 m/s. We also predict that glutamine therapy will increase arginine bioavailability and subsequently alter sickle red cell endothelial interaction that can be identified using endo-PAT technology through nitric oxide (NO) generation, leading to changes in biological markers, and clinical outcome. Specifically our second hypothesis is that oral glutamine will decrease biomarkers of hemolysis and adhesion molecules, and improve the imbalanced arginine-to-ornithine ratio that occurs in hemolytic anemias, leading to improved arginine bioavailability and clinical endpoints of endothelial dysfunction and PH in patients with SCD and Thal.
In this research study, we are using heart imaging exams and blood testing, in order to gain an improved understanding of the pulmonary (lung) hypertension and cardiovascular (heart) complications that often occur in sickle cell patients. Information gathered from the healthy volunteers that participate in this study will be compared to information from the sickle cell patients in this study in order to help further our understanding.
Sickle cell disease (SCD) is often referred to as a hypercoagulable state. However, the contribution of coagulation activation to the pathogenesis of SCD remains uncertain. Pulmonary hypertension (PHT) is a common complication associated with significant morbidity and mortality. Autopsy studies of SCD patients with PHT show evidence of in situ thrombosis involving pulmonary vessels, similar to findings in non-sickle cell patients with PHT. Anticoagulation has been reported to be of benefit in non-sickle cell patients with PHT. With the evidence of increased coagulation activation in SCD, PHT represents a clinical endpoint that may be used to evaluate the contribution of coagulation activation to the pathophysiology of SCD. The investigators hypothesize that increased thrombin generation, as well as platelet activation are central to the pathophysiology of SCD and contribute to the occurrence of several SCD-related complications, including PHT. As a consequence, treatment modalities that down-regulate thrombin generation would be expected to delay the progression of PHT and result in improved survival in patients with SCD.
This study will determine if administration of sodium nitrite is safe and can improve small vessel blood flow and tissue oxygenation when given as an additional treatment in patients with acute vaso-occlusive crisis (pain crisis) associated with sickle cell disease.
Sickle Cell Disease (SCD) is a hereditary anemia that causes the red blood cells to change their shape from a round and doughnut-like shape to a half-moon/crescent, or sickled shape. People who have SCD have a different type of hemoglobin (protein that carries oxygen). This different type of hemoglobin makes the red blood cells change into a crescent shape under certain conditions. Sickle-shaped cells are a problem because they often get stuck in the blood vessels blocking the flow of blood and can cause inflammation and injury to important areas of the body. All babies are born with hemoglobin called fetal hemoglobin (HbF). Soon after birth, HbF production slows down and another hemoglobin called adult hemoglobin (HbA) is made. Clinical studies have shown that increasing the amount of HbF in the blood may prevent sickling of the red blood cells. Vorinostat has been used in the treatment of cancers and in other research studies and information from those suggests that it may help treat SCD by increasing the amount of HbF in the blood. The purpose of this research study is to determine the effectiveness and safety of vorinostat when used to treat SCD.
Patient-Controlled Analgesia (PCA) means that the patient is in control of his/her pain medicine. In this study two (2) different treatment plans of Patient-Controlled Analgesia will be used to treat people with sickle cell disease who are admitted to the hospital for a pain crisis. The purpose of this study is to find out if one plan is better than the other in controlling sickle cell pain. If you are eligible for the study, you will be assigned by chance (like flipping a coin) to either get a higher continuous amount of the pain medicine with a smaller amount for pain as you need it, OR to get a smaller continuous amount of pain medicine with a larger amount of pain medicine as you need it. You or your study doctor can not choose which plan you receive, and you will not be told which one you have been assigned to. The doctors and nurses taking care of you will know which plan you are assigned to so they can safely and effectively take care of your pain. Some members of the study team will not know which plan you are on. We will give you morphine sulfate or hydromorphone (dilaudid) for your pain. These medicines are approved by the Food and Drug Administration (FDA) and have been used for a long time to relieve pain. If you have been treated for pain before with hydromorphone (dilaudid) and you prefer it to morphine, then you may choose to get it during the study. If you have not received hydromorphone (dilaudid) before or you do not have a preference then you will be given morphine for pain. The pain medicine will be given through the IV in your arm. You will receive morphine or hydromorphone continuously through the IV and will also be able to use the PCA machine to give yourself extra pain medicine as you need it for pain. You will need to push a button to give yourself extra medicine for pain. The amount of pain medicine you get on these plans is based on how much you weigh.
Hypothesis: The investigators suspect that significant degrees of iron overload in subjects with SCD result in decreased red cell survival, abnormal endothelial function and markedly dysregulated autonomic function. Furthermore, the investigators anticipate that the magnitude of these effects is proportional not only to the magnitude of total body iron stores but also to the duration of exposure to the high iron levels in tissues. Primary objective To determine if red cell survival as assessed by 51Cr red cell survival analysis, hemoglobin level, reticulocyte count, lactic acid dehydrogenase, and plasma hemoglobin in sickle cell patients is related to the degree of iron overload. Secondary objective(s) 1. Determine if the magnitude of endothelial-dependant vasodilation is related to The degree of iron overload. 2. Determine if the degree of change in cardiac beat to beat variability in response to hypoxic exposure or to cold exposure ("cold-face-test") is related the magnitude of iron overload. The primary measure of iron overload will be MRI determination of liver iron concentration.
Background: Bone marrow transplantation (BMT), which involves transplanting a donor's marrow stem cells, is capable of curing some congenital anemias. BMT usually involves high-intensity treatment with chemotherapy and radiation to kill abnormal cells, which affects all systems of the body. People with anemias often have damage to other organs such as the kidneys, which can be further damaged by the chemotherapy. Only approximately 20 percent of patients have a full-matched donor, making treatment for many people with anemias unavailable. However, 90 percent of patients may have a half-matched donor, but using a half-matched donor increases the toxicity of BMT. Objectives: To determine if a research BMT with half-matched donor cells, low-intensity radiation, immunosuppressant drugs, and no chemotherapy will be effective in patients with sickle cell disease and Beta-thalassemia. To determine the effectiveness of cyclophosphamide, an immunosuppressant drug, in preventing rejection of the donor cells. Eligibility: Recipients are individuals at least 18 years of age who have been diagnosed with sickle cell disease and Beta-thalassemia, and who have a family member who is a haploidentical (i.e., half match) tissue match. Donors are healthy individuals between the ages of 2 and 80 who are found to be suitable donors. Design: Donors will undergo apheresis, which involves withdrawing blood from one arm vein, passing it through a machine that removes bone marrow stem cells, and returning the remaining blood through the vein in the other arm. Donors will receive a drug that causes the stem cells to be released into the bloodstream prior to the apheresis procedure. Recipients will undergo routine physical and laboratory examinations, including bone marrow sampling at the beginning of the study. After transplantation, physical and laboratory examinations will occur on a weekly or twice weekly basis at the outpatient clinic. Recipients will be examined every 6 months starting 100 days posttransplant for 5 years. Recipients will receive low-dose radiation in two treatments 1 and 2 days before the transplant. They will also be given immunosuppressant therapy with alemtuzumab and sirolimus. Another immunosuppressant drug, cyclophosphamide, will be given in the future as needed to subsets of the recipients to prevent rejection of donor cells. Recipients will receive the donor stem cells through a previously inserted central line. The process takes up to 8 hours. Recipients will receive blood transfusions as necessary to prevent anemia and bleeding during the posttransplant period. They may also receive intravenous antibiotics to prevent infection.