View clinical trials related to Non-Hodgkin's Lymphoma.
Filter by:Lenalidomide has been shown to have single agent activity in indolent Non-Hodgkin's Lymphoma. It is approved for the treatment of multiple myeloma and myelodysplastic syndrome. Rituximab is effective as a single agent and in combination with chemotherapy for indolent Non-Hodgkin's Lymphoma. The purpose of this study is to see how well giving lenalidomide together with rituximab works in treating patients with previously untreated indolent Non Hodgkin's Lymphoma. Lenalidomide will taken at 20 mg daily, days 1-21 of a 28 day cycle, to be continued until the disease progresses, unacceptable side effects or after twelve cycles if the patient is responding well. Rituximab 375 mg/m2/wk x 4 weeks will begin on Day 15 of cycle 1. After 4 cycles of therapy, if patients respond well to treatment, patients will receive a second course of Rituximab. Blood samples will be collected to assess how the immune system is functioning.
The purpose of this study is to see how a new drug, named PUH71, accumulates in the different parts of the body & inside tumors and how long PUH71 lasts in the blood, when given to study participants in tiny amounts. The results of this study will help researchers (1) plan how they will use PUH71 as an experimental new drug (at much-higher doses) for the treatment of cancer, in clinical trials; and (2) know whether PUH71 might be used as a drug for detecting tumors with scanner machines.
The body has different ways of fighting infection and disease. No single way seems perfect for fighting cancer. This research study combines two different ways of fighting disease: antibodies and T cells. Antibodies are proteins the protect the body from diseases caused by germs or toxic substances. They work by binding those germs or substances, which stops them from growing and causing bad effects. T cells, also called T lymphocytes, are special infection-fighting blood cells that can kill other cells, including tumor cells or cells that are infected with germs. Both antibodies and T cells have been used to treat patients with cancers: they both have been shown promise, but have not been strong enough to cure most patients. This study combines the two methods. We have found from previous research that we can put a new gene into T cells that will make them recognize cancer cells and kill them. We now want to see if we can attach a new gene to T cells that will help them do a better job at recognizing and killing lymphoma cells. The new gene we will put in T cells makes an antibody called anti-CD30. The antibody alone has not been strong enough to cure most patients. For this study, the anti-CD30 antibody has been changed so that instead of floating free in the blood it is now joined to the T cells. When an antibody is joined to a T cell in this way it is called a chimeric receptor. These chimeric receptor-T cells seem to kill some of the tumor, but they don't last very long and so their chances of fighting the cancer are unknown. We have found that T cells that are also trained to recognize the EBV virus (that causes infectious mononucleosis) can stay in the blood stream for many years. These are called EBV specific Cytotoxic T Lymphocytes. By joining the anti-CD30 antibody to the EBV CTLs, we believe that we will also be able to make a cell that can last a long time in the body and recognize and kill lymphoma cells. We call the final cells CD30 chimeric receptor EBV CTLs. T We hope that these new cells may be able to work longer and target and kill lymphoma cells. However, we do not know that yet.
This is a single-arm study. Key eligibility criteria include (1) newly diagnosed, diffuse large B-cell or follicular cell non-Hodgkin's lymphoma; (2) negative test for hepatitis B surface antigen (HBsAg) and positive for antibody to hepatitis B core antigen (anti-HBc); (3) adequate bone marrow, liver, and kidney function. All eligible patients will receive rituximab-CHOP (cyclophosphamide, doxorubicin, vincristine, prednisolone) chemotherapy according to current treatment guidelines. The primary endpoint of this study is the incidence of hepatitis B virus (HBV) reactivation, defined by a greater than 10-fold increase, compared with previous nadir levels, of HBV DNA during rituximab-CHOP chemotherapy and within 1 year after completion of the last course of rituximab-CHOP chemotherapy. Patients who have HBV reactivation during the study period will receive free entecavir treatment, one of the standard treatment for chronic hepatitis B, for 48 weeks. The secondary endpoints include the incidence of hepatitis flare, defined as a greater than 3 fold increase of serum alanine aminotransferase (ALT) level that exceeded 100 IU/L, and the efficacy and safety of rituximab-CHOP chemotherapy. In the T1408 study we enrolled patients with newly diagnosed lymphoma who were HBsAg (-) and anti-HBc (+) and were to receive rituximab-CHOP (cyclophosphamide, doxorubicin, vincristine, prednisolone)-based chemotherapy. Key findings of this study included (1) HBV reactivation, defined as a greater than 10-fold increase in HBV DNA compared with previous nadir levels, occurred to 10-20% of patients, depending on the sensitivity of the HBV DNA tests; (2) no HBV-related death with the prompt anti-viral therapy upon HBV reactivation; (3) patients with HBV reactivation were associated with poorer progression-free survival and overall survival; (4) serological breakthrough (i.e., re-appearance of HBsAg) is an important predictor of HBV-related hepatitis flare. In this amendment we will enroll more patients to clarify the above findings: (1) the association between HBV reactivation and survival; (2) diagnostic value of quantitative HBsAg and anti HBc tests on HBV reactivation; (3) whether host factors (DNA polymorphism) may help predict HBV reactivation. A larger patient cohort is needed to identify (1) baseline features that may help predict HBV reactivation, and (2) on-treatment features that may help timely anti-viral therapy.
The purpose of this study is to determine if an extended maintenance therapy with Rituximab in follicular and a maintenance therapy in other indolent and mantle cell lymphomas has advantages compared to a shorter or no maintenance therapy.
Subjects are having a bone marrow or SCT for either a type of cancer of the blood called Leukemia or a cancer of the lymph nodes called non- Hodgkin's Lymphoma. Although a transplant can cure leukemia or lymphoma, some people will relapse. In those who relapse, current treatment cures only a very small percentage. Although giving patients a dose of donor immune cells before relapse can prevent relapse of the leukemia or lymphoma, DLI can also cause a serious complication called graft versus host disease (GVHD). This is a gene transfer research study using special immune cells which are specific for these cancer cells. The body has different ways of fighting infection and disease. This study combines 2 of those ways, antibodies and T cells. T cells (CTLs or cytotoxic T cells) are infection-fighting blood cells that can kill cells, including tumor cells. Antibodies and T cells have been used to treat patients with cancers; they have shown promise, but haven't been strong enough to cure most patients. The antibody used in this study is called anti-CD19. This antibody sticks to leukemia cells because of a substance on the outside of these cells called CD19. For this study, the anti-CD19 antibody has been changed so that instead of floating free in the blood it is now joined to T cells. When an antibody is joined to a T cell in this way it's called a chimeric receptor. In the laboratory, investigators found that T cells that are trained to recognize common viruses can stay in the blood stream for many years. By joining the anti-CD19 antibody to CTLs that recognize viruses, they believe that they will also be able to make a cell that can last a long time in the body, provide protection from viruses, and recognize and kill leukemia. The CTLs which we will join the anti-CD19 antibody to attack 3 viruses (trivirus-specific CTLs), CMV, EBV, and adenovirus. Studies have shown that trivirus-specific CTLs grown from the stem cell donor can be given safely to transplant recipients and can stop these viruses from causing severe infections. These CD19 chimeric receptor trivirus specific T cells are an investigational product not approved by the FDA. The purpose of this study is to find the biggest dose of chimeric T cells that is safe, to assess the side effects, to see how long the T cells last and to evaluate whether this therapy might help prevent infections and relapse in people with CD19+ leukemia or lymphoma having a SCT.
This is a Phase 1 study evaluating the safety of ABT-263 administered in combination with rituximab in participants with CD20-positive lymphoproliferative disorders. The extension portion of the study will allow active participants to continue to receive ABT-263 for up to 13 years after the last participant transitions with quarterly study evaluations.
Patients are being asked to participate in this study because they will be receiving a stem cell transplant as treatment for their disease. As part of the stem cell transplant, they will be given very strong doses of chemotherapy, which will kill off all their existing stem cells. Stem cells are created in the bone marrow. They grow into different types of blood cells that we need, including red blood cells, white blood cells, and platelets. We have identified a close relative of the patients whose stem cells are not a perfect match for the patient, but can be used. This type of transplant is called "allogeneic", meaning that the cells come from a donor. With this type of donor who is not a perfect match, there is typically an increased risk of developing graft-versus-host disease (GvHD) and a longer delay in the recovery of the immune system. GvHD is a serious and sometimes fatal side effect of stem cell transplant. GvHD occurs when the new donor cells recognize that the body tissues of the patient are different from those of the donor. In the laboratory, we have seen that cells made to carry a gene called iCasp9 can be killed when they encounter a specific drug called AP1903. To get the iCasp9 into the T cells, we insert it using a virus called a retrovirus that has been made for this study. The drug (AP1903) that will be used to "activate" the iCasp9 is an experimental drug that has been tested in a study in normal donors, with no bad side effects. We hope we can use this drug to kill the T cells. Other drugs that kill or damage T cells have helped GvHD in many studies. However we do not yet know whether AP1903 will kill T cells in humans, even though it has worked in our experimental studies on human cells in animals. Nor do we know whether killing the T cells will help the GvHD. Because of this uncertainty, patients who develop significant GvHD will also receive standard therapy for this complication, in addition to the experimental drug. We hope that having this safety switch in the T cells will let us give higher doses of T cells that will make the immune system recover faster. These specially treated "suicide gene" T cells are an investigational product not approved by the Food and Drug Administration.
The purpose of this study is to find answers to the following questions: - What is the largest dose of AQ4N that can be given safely one time every three weeks for 24 weeks? - What are the side effects of AQ4N when given according to this schedule? - How much AQ4N is in the blood at certain times after administration and how does the body get rid of the drug? - Will AQ4N help treat lymphoid cancer?
The purposes of this study are to determine: - the largest dose of AQ4N that can be safely given once a week for three weeks out of a 4 week cycle - the side effects of AQ4N when given on the above schedule - how much AQ4N is in the blood and urine at specific times after administration and how the body get rids of AQ4N - if AQ4N helps treat cancer