View clinical trials related to Anemia.
Filter by:RATIONALE: Drugs used in chemotherapy, such as docetaxel and cisplatin, work in different ways to stop tumor cells from dividing so they stop growing or die. Chemoprotective drugs, such as dimesna, may help prevent or decrease the side effects (such as nerve, kidney, and inner ear damage) caused by chemotherapy. PURPOSE: This randomized phase II trial is studying giving docetaxel and cisplatin together with dimesna to see how well it works compared to giving docetaxel and cisplatin alone in treating patients with stage IIIB or stage IV non-small cell lung cancer.
RATIONALE: Ro 50-3821 may stimulate red blood cell production and treat anemia in patients who are receiving antineoplastic therapy for non-small cell lung cancer. PURPOSE: This randomized phase II trial is studying six different regimens of Ro 50-3821 to compare how well they work in treating anemia in patients who are receiving antineoplastic therapy for stage IIIB or stage IV non-small cell lung cancer.
The purpose of this study is to compare liberal red blood cell transfusion therapy with restrictive red blood cell transfusion therapy in surgical patients with cardiovascular disease or risk factors.
RATIONALE: Darbepoetin alfa and epoetin alfa may stimulate red blood cell production and treat anemia in patients who are receiving chemotherapy. It is not yet known whether darbepoetin alfa is more effective than epoetin alfa in treating patients with anemia. PURPOSE: Randomized phase III trial to compare the effectiveness of darbepoetin alfa with that of epoetin alfa in treating anemia in patients who are receiving chemotherapy for cancer.
Severe aplastic anemia, characterized by pancytopenia and a hypocellular bone marrow, is effectively treated by immunosuppressive therapy, usually a combination of antithymocyte globulin (ATG) and cyclosporine (CsA). Survival rates following this regimen are equivalent to those achieved with allogeneic stem cells transplantation. However, approximately 1/3 of patients will not show blood count improvement after ATG/CsA. General experience and small pilot studies have suggested that such patients may benefit from further immunosuppression. Furthermore, analysis of our own clinical data suggest that patients with poor blood count responses to a single course of ATG, even when transfusion-independence is achieved, have a markedly worse prognosis than patients with robust hematologic improvement. The management of such cases is uncertain. This study will enroll patients who are either refractory to h-ATG (continued severe pancytopenia) or who have only modest improvement in blood counts (weak hematologic responders) to receive a further immunosuppressive therapy, delivered either as rabbit ATG (Thymoglobulin, r-ATG) or a humanized monoclonal antibody to T-cells, alemtuzumab (Campath-1H ). Primary endpoint will be response rate at 3 months defined as no longer meeting criteria for severe aplastic anemia. Relapse, robustness of hematopoietic recovery at 3 months, survival and clonal evolution to paroxysmal nocturnal hemoglobinuria (PNH), myelodysplasia and acute leukemia will be the secondary endpoints.
The purpose of this study is to determine the effects of the oral iron chelator Deferasirox on liver iron content after one year of treatment in patients with iron overload from repeated blood transfusions. Beta-thalassemia patients unable to be treated with deferoxamine or patients with rare chronic anemias such as Myelodysplastic Syndrome, Fanconi's Syndrome, Blackfan-Diamond Syndrome, and Pure Red Blood Cell Anemia are eligible for this study. Liver iron content will be measured by liver biopsy at the beginning of the study and after one year of treatment. However, those patients living in the San Francisco/Oakland area may have a SQUID in place of the liver biopsy if the biopsy is not medically possible for them. The SQUID is a non-invasive magnetic means to measure liver iron content.
People with severe congenital anemias, such as sickle cell anemia and beta-thalassemia, have been cured with bone marrow transplantation (BMT). The procedure, however, is limited to children younger than the age of 16 because the risks are lower for children than for adults. The purpose of this study is to explore the use of a BMT regimen that, instead of chemotherapy, uses a low dose of radiation, combined with two immunosuppressive drugs. This type BMT procedure is described as nonmyeloablative, meaning that it does not destroy the patient s bone marrow. It is hoped that this type of BMT will be safe for patients normally excluded from the procedure because of their age and other reasons. To participate in this study, patients must be between the ages of 18 and 65 and have a sibling who is a well-matched stem-cell donor. Beyond the standard BMT protocol, study participants will undergo additional procedures. The donor will receive G-CSF by injection for five days; then his or her stem cells will be collected and frozen one month prior to BMT. Approximately one month later, the patient will be given two immune-suppressing drugs, Campath 1-H and Sirolimus, as well as a single low dose of total body irradiation and then the cells from the donor will be infused. Prior to their participation in this study, patients will undergo the following evaluations: a physical exam, blood work, breathing tests, heart-function tests, chest and sinus x-rays, and bone-marrow sampling. ...
Severe aplastic anemia (SAA) is a life-threatening bone marrow failure disorder characterized by pancytopenia and a hypocellular bone marrow. Allogeneic bone marrow transplantation and immunosuppressive treatment with anti-thymocyte globulin (ATG) and cyclosporine (CsA) have dramatically changed the natural course of this illness, with 5 year survival of 75% in patients undergoing either treatment. Since most patients are not suitable candidates for hematopoietic stem cell transplantation (HSCT) due to advanced age or lack of a histocompatible sibling, efforts at NHLBI have focused on improving immunosuppression treatment in order to improve response rates, survival, and to decrease relapse. In our experience of 122 patients treated at NHLBI with the combination of ATG and cyclosporine, one quarter to one third did not respond; about 50% of responders relapsed; and 5 year survival was correlated with the robustness in blood cell count improvement at 3 months (reticulocyte or platelet count greater than or equal to 50,000 /uL). Why some patients do not respond initially while others relapse is unclear. Autoreactive T cells may be resistant to the effect of ATG/CsA (nonresponders), while in others residual autoreactive T cells expand post-treatment leading to hematopoietic stem cell destruction and recurrent pancytopenia (relapse). Therefore, novel immunosuppressive regimens to increase response rates and hematologic recovery at 3 months and to decrease relapse rates are needed. An ongoing NHLBI trial, which is close to completing accrual, has added mycophenolate mofetil (MMF) for a total of 18 months to standard ATG + CsA in an attempt to reduce the relapse rate after cyclosporine is discontinued. Preliminary results have been disappointing, with no marked reduction in relapse among patients who received MMF. Sirolimus (rapamycin, Rapamune , RAPA) is a novel immunosuppressive agent, which acts synergistically with cyclosporine by blocking T cell activation through CsA-resistant pathways. The potentiation of the combination of CsA-RAPA has been established in vitro and in the clinical setting, mainly in islet cell and solid organ transplantation. The significant increase in response rate seen with the addition of CsA to ATG indicated that an inhibitory effect on T lymphocytes is important in blocking autoreactive T cells in aplastic anemia. The combination of CsA-RAPA may further block activated autoreactive T cells and therefore lead to improved response rates (and survival) and decreased relapse rates. This prospective randomized phase II study will investigate two different immunosuppressive regimens in patients with severe aplastic anemia who have not received prior immunosuppressive therapy. One arm will receive ATG + CsA in addition to sirolimus for 6 months, and the second arm will receive standard ATG + CsA for 6 months followed by a slow taper of CsA with a 25% dose reduction every 3 months for the subsequent 18 months. This trial will determine the effectiveness of sirolimus in patients with aplastic anemia as well as the role of a cyclosporine taper in preventing relapses. Primary endpoint will be no longer meeting criteria for severe aplastic anemia while secondary endpoints are relapse, robustness of hematologic recovery at 3 months, survival, clonal evolution to PNH, myelodysplasia and acute leukemia. 10/11/2005. The Sirolimus (Rapamune) arm of the trial was stopped for lack of efficacy. The study will continue as a single arm study to establish if slow taper of CsA prevents relapse rates after initial standard treatment with ATG followed by CsA for six months.
RATIONALE: Epoetin alfa may stimulate red blood cell production and may help improve cancer-related anemia and fatigue. Steroid therapy with dexamethasone may increase the effectiveness of epoetin alfa. It is not yet known if epoetin alfa is more effective with or without dexamethasone in treating anemia-related fatigue in patients with prostate cancer. PURPOSE: This randomized phase III trial is studying epoetin alfa and dexamethasone to see how well they work compared to epoetin alfa alone in treating anemia-related fatigue in patients with prostate cancer that is refractory to treatment with hormone therapy.
RATIONALE: Epoetin alfa may stimulate red blood cell production and treat anemia in patients with solid tumors. It is not yet known whether epoetin alfa given once a week is more effective than epoetin alfa given once every 3 weeks in treating anemia. PURPOSE: Randomized phase III trial to study the effectiveness of epoetin alfa in treating anemia in patients who have solid tumors.