View clinical trials related to Anemia.
Filter by:Background: A prospective cohort of Inherited Bone Marrow Failure Syndrome (IBMFS) will provide new information regarding cancer rates and types in these disorders. Pathogenic variant(s) in IBMFS genes are relevant to carcinogenesis in sporadic cancers. Patients with IBMFS who develop cancer differ in their genetic and/or environmental features from patients with IBMFS who do not develop cancer. These cancer-prone families are well suited for cancer screening and prevention trials targeting those at increased genetic risk of cancer. Carriers of IBMFS pathogenic variant(s) are at increased risk of cancer. The prototype disorder is Fanconi's Anemia (FA); other IBMFS will also be studied. Objectives: To determine the types and incidence of specific cancers in patients with an IBMFS. To investigate the relevance of IBMFS pathogenic variant(s) in the carcinogenesis pathway of the sporadic counterparts of IBMFS-associated cancers. To identify risk factors for IBMFS-related cancers in addition to the primary germline pathogenic variant(s). To determine the risk of cancer in IBMFS carriers. Eligibility: North American families with a proband with an IBMFS. IBMFS suspected by phenotype, confirmed by pathogenic variant(s) in an IBMFS gene, or by clinical diagnostic test. Fanconi's anemia: birth defects, marrow failure, early onset malignancy; positive chromosome breakage result. Diamond-Blackfan anemia: pure red cell aplasia; elevated red cell adenosine deaminase. Dyskeratosis congenita: dysplastic nails, lacey pigmentation, leukoplakia; marrow failure. Shwachman-Diamond Syndrome: malabsorption; neutropenia. Amegakaryocytic thrombocytopenia: early onset thrombocytopenia. Thrombocytopenia absent radii: absent radii; early onset thrombocytopenia. Severe Congenital Neutropenia: neutropenia, pyogenic infections, bone marrow maturation arrest. Pearson's Syndrome: malabsorption, neutropenia, marrow failure, metabolic acidosis; ringed sideroblasts. Other bone marrow failure syndromes: e.g. Revesz Syndrome, WT, IVIC, radio-ulnar synostosis, ataxia-pancytopenia. First degree relatives of IBMFS-affected subjects as defined here, i.e. siblings (half or full), biologic parents, and children. Grandparents of IBMFS-affected subjects. Patients in the general population with sporadic tumors of the types seen in the IBMFS (head and neck, gastrointestinal, and anogenital cancer), with none of the usual risk factors (e.g. smoking, drinking, HPV). Design: Natural history study, with questionnaires, clinical evaluations, clinical and research laboratory test, review of medical records, cancer surveillance. Primary endpoints are all cancers, solid tumors, and cancers specific to each type of IBMFS. Secondary endpoints are markers of pre-malignant conditions, such as leukoplakia, serum or tissue evidence of carcinogenic viruses, and bone marrow morphologic myelodyplastic syndrome or cytogenetic clones....
This study will test whether inhaling nitric oxide (NO) gas mixed with room air can improve pulmonary hypertension (high blood pressure in the lungs) in patients with sickle cell anemia. Patients with sickle cell disease 18 years of age or older may be eligible to participate in one or more parts of this three-stage study, as follows: Stage 1 Patients undergo the following tests to determine the cause of their pulmonary hypertension: blood tests; echocardiogram (heart ultrasound); asthma test; oxygen breathing study with measurement of arterial blood oxygen levels; chest X-ray; lung scans; MRI of the heart; 6-minute walk test; night-time oxygen measurement while sleeping; and exercise studies. Stage 2 Patients have a detailed MRI evaluation of the heart and are admitted to the NIH Clinical Center intensive care unit (ICU) for the following test: A plastic tube is placed in a vein in the patient's arm and another tube is placed in a deeper neck or leg vein. A third tube is inserted through the vein into the heart and the lung artery to measure blood pressures in the heart and lungs directly. Following baseline measurements, three medications (inhaled oxygen, infused prostaglandin, and inhaled NO) are delivered for 2 hours each, separated by a 30-minute washout period. A small blood sample is drawn during the NO administration. Patients who cannot be treated with nitric oxide or for whom the treatment does not work may receive monthly exchange transfusions for 3 months. For this procedure, 3 to 5 five units of the patient's blood is removed and replaced with 3 to 5 units that do not have sickle hemoglobin. Some patients who do not respond to NO or exchange transfusions may receive an alternative therapy, such as oxygen, prostacyclin, L-arginine, bosentan or sidenafil. Stage 3 Patients remain in the ICU with catheters in place for another 24 hours. During this time they breathe NO. Lung pressures are measured every 4 hours and blood is drawn every 8 hours. They then stay in the hospital 1 more day for observation. Patients then breathe nitric oxide continuously for 2 months using a tank of gas that delivers the NO through tubes placed in the nose. They may do this at home on an outpatient basis or may remain in the hospital for the 2 months. Patients have an echocardiogram and blood tests every week and do a 6-minute walk test every 2 weeks....
RATIONALE: Epoetin alfa may stimulate red blood cell production to treat patients who have anemia following chemotherapy. PURPOSE: Phase IV trial to study the effectiveness of epoetin alfa in treating chemotherapy-related anemia in women who have stage I, stage II, or stage III breast cancer.
OBJECTIVES: I. Determine the effect of supplementation with donor T-cell depleted, CD34+ peripheral blood stem cells on durable engraftment and incidence of graft-versus-host disease in patients with aplastic anemia undergoing allogeneic bone marrow transplantation.
Drugs used in chemotherapy use different ways to stop tumor cells from dividing so they stop growing or die. Radiation therapy uses high-energy x-rays to damage tumor cells. Epoetin alfa may stimulate red blood cell production to treat anemia in patients who have received chemotherapy and/or radiation therapy for cervical cancer. Randomized phase III trial to study the effectiveness of epoetin alfa in treating anemia in patients who have cervical cancer.
Phase II trial to study the effectiveness of thalidomide in treating patients who have myelodysplastic syndrome. Thalidomide may improve the immune system's ability to fight myelodysplastic syndrome
Drugs used in chemotherapy use different ways to stop cancer cells from dividing so they stop growing or die. Colony-stimulating factors such as sargramostim may increase the number of immune cells found in bone marrow or peripheral blood and may help a person's immune system recover from the side effects of chemotherapy. Phase I trial to study the effectiveness of bryostatin 1 combined with sargramostim in treating patients who have refractory myeloid cancer
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.