View clinical trials related to Leukemia, Lymphoid.
Filter by:RATIONALE: Drugs used in chemotherapy use different ways to stop cancer cells from dividing so they stop growing or die. Combining chemotherapy with peripheral stem cell transplantation may allow the doctor to give higher doses of chemotherapy drugs and kill more cancer cells. PURPOSE: Phase II trial to study the effectiveness of combination chemotherapy followed by peripheral stem cell transplantation in treating children who have relapsed acute lymphocytic leukemia.
RATIONALE: Drugs used in chemotherapy work in different ways to stop cancer cells from dividing so they stop growing or die. Combining chemotherapy with allogeneic or autologous stem cell transplantation may allow the doctor to give higher doses of chemotherapy drugs and kill more cancer cells. It is not yet known whether stem cell transplantation is more effective than standard chemotherapy in treating acute lymphoblastic leukemia. PURPOSE: This randomized phase III trial is studying how well stem cell transplantation works compared to standard combination chemotherapy in treating patients with acute lymphoblastic leukemia in first remission.
RATIONALE: Drugs used in chemotherapy use different ways to stop cancer cells from dividing so they stop growing or die. Combining more than one drug may kill more cancer cells. PURPOSE: Phase II trial to study the effectiveness of combination chemotherapy in treating patients who have acute B-lymphoblastic leukemia or recurrent non-Hodgkin's lymphoma.
Cancers of the blood, sometimes referred to as hematologic malignancies, are disorders of bone marrow cells that lead to the failure of the normal function of bone marrow and the uncontrolled growth of cancerous cells in the bone marrow. These cancerous cells can spill over into the bloodstream and affect other organs causing widespread symptoms. The disease is life threatening because it blocks the normal function of the marrow, which is to produce red cells (preventing anemia), white cells (preventing infection), and platelets (preventing progression). Bone marrow transplants are a potential form of therapy for patients with hematologic malignancies. However, BMT is a complicated procedure and can be associated with dangerous side effects. In this study researchers are attempting to find ways to reduce the complications of BMT, so that it would be possible to use it more safely and can be offered more patients. In order to do this, researchers are developing new techniques to make BMT safer. It requires making small changes to the standard procedure, which may improve the outcome. The experimental procedures researchers are evaluating are: 1. <TAB>T-cell depleted peripheral blood progenitor cell (PBPC) transplantation 2. <TAB> Cyclosporine given immediately after the transplant 3. <TAB>Add-back of donor lymphocytes Patients undergoing these experimental techniques must be monitored closely to see if any benefit or harmful effects will occur. Information gathered from this study can be used to develop further research studies and potential new therapies for hematologic malignancies.
Allogeneic peripheral blood stem cell transplantation (PBSCT) is primarily limited by graft-versus-host disease (GVHD). In murine models, we have demonstrated that donor CD4+ T cells of Th1 cytokine phenotype (defined by their secretion of IL-2 and IFN-gamma) mediate GVHD. In contrast, donor CD4+ T cells of Th2 phenotype (defined by their secretion of IL-4, IL-5, and IL-10) do not generate GVHD, and abrogate Th-1-mediated GVHD. Importantly, we have demonstrated that enrichment of murine allografts with Th2 cells reduces GVHD without impairing the ability of donor T cells to prevent graft rejection. These studies indicate that the administration of Th2 cells after allogeneic transplantation represents a strategy for achieving alloengraftment with reduced GVHD. In addition to GVHD, allogeneic PBSCT has been limited by the toxicity associated with conventional myeloablative preparative regimens. Such regimens, which typically utilize total body irradiation (TBI) and high-dose chemotherapy, were once considered essential for the prevention of graft rejection. However, recent clinical studies have shown that non-myeloablative doses of fludarabine-based chemotherapy can result in alloengraftment. In murine models, we have demonstrated that severe host T cell depletion induced by combination fludarabine and cytoxan can prevent even fully-MHC mismatched marrow graft rejection. Although non-myeloablative regimens may reduce regimen-related toxicity, such transplants have been associated with a 30 to 40% incidence of severe acute GVHD that is similar to rates observed with myeloablative regimens. Because non-myeloablative regimens appear to be associated with reduced regimen-related toxicity, we have elected to conduct this phase I study of Th2 cells in the setting of an immunoablative (non-myeloablative) preparative regimen. Patients with leukemia in clinical remission, and patients with refractory lymphoid malignancy will be candidates for this HLA-matched allogeneic PBSCT protocol. Patients will receive novel induction regimen (fludarabine and EPOCH) and transplant preparative regimen (fludarabine and cytoxan) designed to maximally deplete host immune T cells capable of mediating graft rejection. After induction and preparative regimen chemotherapy, patients will receive an unmanipulated, G-CSF mobilized PBSC graft. In the initial six patients receiving this transplant procedure at the NCI, graft rejection has been successfully prevented (100% donor chimerism by day 30 post-transplant). Importantly, GVHD has been observed in all six patients, with three of the six patients developing severe GVHD (grade III). Given that this regimen successfully achieves donor engraftment, and is associated with significant GVHD, this transplant regimen represents an excellent clinical setting for the evaluation of Th2 cells. Using this non-myeloablative allogeneic PBSCT approach, we will perform a Phase I study to evaluate the safety and feasibility of administering donor Th2 cells on day 1 post-transplant. Prior to transplantation, donor CD4+ T cells will be stimulated in vitro using culture conditions that support the generation of donor CD4 cells of the Th2 cytokine profile. If this Phase I study demonstrates that Th2 cell administration is safe and feasible, a Phase III study will be performed to evaluate whether Th2 cell administration reduces the incidence and severity of GVHD. Successful implementation of this Th2 strategy will greatly reduce the morbidity and mortality associated with allogeneic PBSCT, and may also represent an approach to stem cell transplantation in patients lacking an HLA-matched donor.
The pharmacokinetic behavior of vincristine in pediatric patients has not been well characterized. The present study will obtain detailed information on vincristine pharmacokinetics in patients being treated for standard risk ALL on CCG protocols 1952/1962. A limited sampling strategy will be developed, and the interpatient and intrapatient variability of vincristine pharmacokinetics in children will be studied. A correlation between vincristine neurotoxicity and vincristine pharmacokinetics will be sought.
Diseases such as leukemia, lymphoma, and multiple myeloma fall into the category of blood cancers. Some of these conditions can now be cured by bone marrow transplantation (BMT). The ability of BMT to cure these conditions has been credited to the use of high doses of chemotherapy, radiation therapy, and the antileukemia effect of the transplant. Because the effectiveness of BMT relies on the use of high doses of chemotherapy and total body irradiation (TBI), it is a therapy associated with toxic side effects. These side effects are often deadly and have limited BMT for use in patients under the age of 55. In this study researchers plan to treat older patients between the ages of 55 to 75 years with blood cell transplants taken from donors who are genetically matched relatives of the patient. In order to decrease the toxic side effects associated with the transplant, researchers will not use chemoradiotherapy. Instead they plan to use intensive immunosuppressive therapy and allow the transplanted cells to take effect.
Background: - Combined therapy with rituximab and fludarabine is the treatment of choice for advanced stage chronic lymphocytic leukemia/small lymphocytic lymphoma (CLL/SLL). - A new technology called deoxyribonucleic acid (DNA) microarray can be used to gain knowledge about the genetic basis of CLL/SLL. - Genetic studies of CLL/SLL may improve our understanding of what happens in the disease, help determine which patients are most likely to respond to treatment with fludarabine and rituximab, and identify new treatments. Objectives: -To gain further knowledge about CLL/SLL and the role of rituximab and fludarabine in treating the disease. Eligibility: -Patients 18 years of age and older with low, intermediate or high-risk CLL/SLL. Design: - Patients with low-risk CLL/SLL do not receive treatment, but are followed every 3 to 6 months and donate cells (through apheresis) or lymph nodes, or both, for research purposes. - Patients with intermediate or high-risk CLL/SLL receive standard treatment with rituximab and fludarabine for six 28-day treatment cycles. Rituximab is given on day 1 and fludarabine is given on days 1-5. (For the first cycle only, fludarabine treatment starts on day 2. This delay permits blood sampling on day 1 for the effect of rituximab on white blood cells.) - Laboratory tests and imaging studies are done periodically to monitor drug side effects and the response to treatment. Tests include bone marrow biopsy and aspiration, blood tests and x-rays, including positron emission tomography (PET) and computed tomography (CT) scans.