View clinical trials related to Anemia.
Filter by:This study will examine 1) whether it is possible to collect enough stem cells (cells produced by the bone marrow that mature into white and red blood cells and platelets) from patients with aplastic anemia to use for future treatment, and 2) whether patients who have been treated successfully and relapse will benefit from autologous stem cell transfusion (transfusion of their own stem cells). Patients 12 years of age or older with aplastic anemia who have been successfully treated with immunosuppressive drugs and are now in remission may be eligible for this study. Participants will undergo a complete history and physical examination, bone marrow biopsy (removal of a small sample of bone marrow from the hip bone) and blood tests, plus procedures to collect stem cells, as follows: - G-CSF (Filgrastim) administration - G-CSF will be given by injection under the skin daily for up to 10 days. This drug causes stem cells to move from the marrow into the blood where they can be collected more easily. - Apheresis - Stem cells will be collected through apheresis, usually starting the 5th to 6th day of Filgrastim injections. For this procedure, whole blood is collected through a needle in an arm vein. The blood circulates through a cell separator machine where the white cells and stem cells are removed. The red cells, platelets and plasma are returned to the body through a second needle in the other arm. The procedure takes about 5 hours. Up to five procedures, done on consecutive days, may be required to collect enough cells for transplantation. If enough cells are collected, they will be purified (treated to remove the white blood cells) using an experimental device. Removing the lymphocytes may reduce the chance of relapse of aplastic anemia following the stem cell transplant. The stem cells will be frozen for later use, if needed. - Follow-up - Participants are followed at NIH at 6-month intervals.
The purpose of this study is to determine how often people with sickle cell anemia develop pulmonary hypertension a serious disease in which blood pressure in the artery to the lungs is elevated. Men and women 18 years of age and older with sickle cell anemia may be eligible for this study. Participants will undergo an evaluation at Howard University s Comprehensive Sickle Cell Center in Washington, D.C. or at the National Institutes of Health in Bethesda, Maryland. It will include the following: - medical history - physical examination - blood collection (no more than 50 ml., or about 1/3 cup) to confirm the diagnosis of sickle cell anemia, sickle cell trait or beta-thalassemia (Some blood will be stored for future research testing on sickle cell anemia.) - echocardiogram (ultrasound test of the heart) to check the pumping action of the heart and the rate at which blood travels through the tricuspid valve. Following this evaluation, a study nurse will contact participants twice a month for 2 months and then once every 3 months for the next 3 years for a telephone interview. The interview will include questions about general health and recent health-related events, such as hospitalizations or emergency room visits.
This study will provide information needed to develop more effective treatments for patients with Diamond-Blackfan anemia (DBA). Current treatments include steroids, such as prednisone, and blood transfusions. These treatments have potential long-term risk and side effects, including osteoporosis and impaired growth from steroids or iron overload from transfusions. In addition, as patients reach adulthood, they can develop acute leukemia or bone marrow failure. The only cure for DBA is bone marrow transplant, a procedure that itself carries serious risks and is an option for only about 25 percent of patients. DBA is caused by a mutation (error) in a gene that codes for producing red blood cells from stem cells (blood-forming cells produced by the bone marrow). In 5 to 10 years, gene transfer therapy may prove to be an effective treatment for DBA. Before this treatment can be considered, however, more information is needed about DBA patients and how their stem cells function. This study will examine: 1) whether stem cells of patients with DBA respond to G-CSF the same way those of healthy people do. (G-CSF is a drug that causes stem cells to move from the bone marrow to the blood stream, where they can be collected more easily and in larger numbers by a procedure called leukapheresis, described below. If G-CSF does not work well in DBA patients, other collection strategies will have to be explored); and 2) whether the genetic error in DBA can be corrected by gene transfer into patients' stem cells. Patients with Diamond-Blackfan anemia 4 years of age and older who weigh at least 27 pounds and who are dependent on red blood cell transfusions may be eligible for this study. Candidates will have a medical history taken and a physical examination and will be seen by the Clinical Center's Department of Medicine Transfusion for leukapheresis evaluation. They will have a bone marrow aspiration and biopsy to confirm the diagnosis of DBA. For these tests, the hip area is anesthetized and a needle is used to draw bone marrow from the hipbone. If needed, the procedure will be done under sedation. Patients will be given G-CSF by injection under the skin for up to 6 days. Blood and stem cell counts will be measured from a teaspoon of blood drawn each morning. On the morning of the fifth dose, the patient will undergo leukapheresis for collection of stem cells. For this procedure, a large catheter (with a diameter no larger than that of a straw) is placed in an arm vein to allow blood to flow into a cell separator machine. Most children and some adults do not have veins large and strong enough for this tubing, so a large intravenous line called a "central line" is placed into a large vein in the neck or groin. This is done under sedation and with a local anesthetic. While the patient lies on a bed or recliner, whole blood is collected through a catheter in one arm or the central line, the stem cells are separated out by spinning, then the red cells, platelets and plasma are returned through a second catheter in the other arm or a second opening in the central line. The procedure takes about 3 to 5 hours, during which the patient can watch television or videos and have family members at the bedside for company. When the procedure is completed, the patient's participation in the protocol ends. Some of the stem cells collected by leukapheresis will be used for research and some will be frozen and stored for possible future transplantation into the patient, if required.
This phase I trial studies the side effects and best dose of iodine I 131 monoclonal antibody BC8 when given together with fludarabine phosphate and low-dose total-body irradiation followed by donor stem cell transplant and immunosuppression therapy in treating older patients with acute myeloid leukemia or high-risk myelodysplastic syndromes that cannot be controlled with treatment. Radiolabeled monoclonal antibodies, such as iodine I 131 monoclonal antibody BC8, can find cancer cells and carry cancer-killing substances to them. Giving chemotherapy, such as fludarabine phosphate, and total-body irradiation before a donor peripheral blood stem cell transplant helps stop the growth of cancer or abnormal 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. Sometimes the transplanted cells from a donor can also make an immune response against the body's normal cells. Giving radiolabeled monoclonal antibody therapy together with fludarabine phosphate and total-body irradiation before the transplant together with cyclosporine and mycophenolate mofetil after the transplant may stop this from happening.
The purpose of this study is to determine if hydroxyurea therapy is effective in the prevention of chronic end organ damage in pediatric patients with sickle cell anemia.
The purposes of this study are threefold: 1) to evaluate the prevalence and risks of oral complications in patients with aplastic anemia; 2) to evaluate if oral problems in these patients can predict their response to treatment; and 3) to review complications of dental treatment in these patients in order to establish treatment guidelines. This study will be performed through a review of medical charts of 79 patients with aplastic anemia and 67 patients with schizophrenia who were treated at the National Institutes of Health Dental Clinic between 1993 and 1999. The schizophrenia patients will serve as a control population. Demographic, clinical and radiographic information will be collected for all patients. Additional data collected only for aplastic anemia patients will include medical therapy, disease duration, blood cell counts, oral problems that developed during treatment and treatment response.
Drugs used in chemotherapy use different ways to stop cancer cells from dividing so they stop growing or die. Phase I trial to study the effectiveness of BMS-214662 in treating patients who have acute leukemia, myelodysplastic syndrome, or chronic myeloid leukemia in blast phase
Phase I/II trial to study the effectiveness of liposomal daunorubicin and SU5416 in treating patients who have hematologic cancer that has not responded to initial therapy. Drugs used in chemotherapy use different ways to stop cancer cells from dividing so they stop growing or die. SU5416 may stop the growth of hematologic cancer by stopping blood flow to the cancer
This study will examine the safety and effectiveness of a new drug combination for treating patients with severe aplastic anemia. Patients with aplastic anemia produce too few blood cells, causing fatigue, easy bruising and bleeding, and susceptibility to infections. In many cases, the very low blood counts result from an autoimmune process-that is, the patient's own immune system suppresses production of blood cells by the bone marrow. Although immune-suppressing drugs, such as cyclosporine, can restore normal cell counts, many patients have disease relapses. These patients require long-term therapy with cyclosporine, which can cause harmful side effects. This study will examine whether a lower dose of cyclosporine given together with mycophenolate mofetil (MMF) can maintain blood counts as effectively as full-dose cyclosporine treatment, and whether MMF alone can reduce the chances of future relapses. Patients 4 years of age and older with severe aplastic anemia who have relapsed after immune suppressing therapy may be eligible for this study. Participants will be randomly assigned to receive either standard cyclosporine therapy or experimental therapy with cyclosporine and MMF. Patients receiving standard cyclosporine therapy will receive a full dose of the drug for at least 3 months. Those taking both cyclosporine and MMF will take MMF plus half-dose cyclosporine for 3 months and continue MMF for an additional 6 months. Both drugs are taken twice a day by mouth. All patients will have about 120 milliliters (4 ounces) of blood drawn at the beginning of the study to evaluate immune system activity and bone marrow function, and to look for genetic material of certain viruses. Bone marrow aspirations and biopsies will be done at the beginning of the study, and at 6 and 12 months. For these tests, the area of the hip is anesthetized and a special needle is used to draw bone marrow from the hipbone. The patient's local doctor will be asked to do blood tests for chemistries, liver function and cyclosporine levels weekly for the first month and then every other week. Patients will return to NIH for evaluations 3, 6 and 12 months after treatment and then once a year. About 100 ml (7 tablespoons) of blood will be drawn at each visit.
OBJECTIVES: I. Determine the effectiveness of moderate dose cyclophosphamide and radiotherapy in terms of improving survival and reducing the morbidity following allogeneic bone marrow transplantation in patients with myelodysplastic syndrome and acute leukemia related to Fanconi's anemia.