View clinical trials related to Hodgkin's Disease.
Filter by:This study is for patients with relapsed of disease after allogeneic bone marrow The donor's T cells are activated by exposure to 2 compounds or antibodies that bind (or stick to) two compounds on T cells called CD3 and CD28. When these antibodies stick to both CD3 and CD28 on the T cells, the T cells becomes stimulated (or "activated") and grows. CD3 and CD28 are the coating of a T cell and a T cell is part of the body's immune system. It is believed that when T cells are exposed to both of antibodies to CD3 and CD28 compounds at the same time, they become activated or "stimulated" and may be more effective in fighting infections or cancer cells. We call this therapy "activated donor lymphocyte infusions, or activated DLI (aDLI)". This current study is being performed to see whether it is safe and effective to administer higher doses of activated DLI or repeated doses of activated DLI. All patients will receive standard donor lymphocyte infusions first, and in addition will receive activated donor lymphocytes approximately 12 days later (DLI followed by aDLI). Depending on the response to this treatment, and depending on possible side effects (such as graft-vs-host disease as described below), patients in remission will then receive additional aDLI every 3 months for 4 more times, and patients not in remission within 6-12 weeks will receive higher dose aDLI. The timing of the higher dose aDLI will be determined by your physician depending on your disease and the rate of progression of your disease. The aDLI can be given as early as 6 weeks, or as late as 12 weeks (3 months).
The purpose of this study is to replace a drug with many side effects, procarbazine, with a new novel drug, vorinostat, in a drug combination for the treatment of patients with diffuse large B-cell lymphoma. Vorinostat is the first of a new type of chemotherapy drug, known as a histone deacetylase inhibitor, to be approved by the Food and Drug Administration. It is approved for the treatment of certain lymphomas of the skin. It alters the cancer cell pathway by preventing cancer cells from reproducing. Vorinostat will be added to a combination of four other effective chemotherapy drugs that have been used for many years for the treatment of diffuse large B-cell lymphoma: rituximab, cyclophosphamide, etoposide and prednisone. The doses of vorinostat will be increased or decreased depending on the side effects that occur in each of the first few patients in the trial to find the safest dose with the least side effects. This is termed the phase I part of the clinical trial. Once the best dose of vorinostat is found, the rest of the patients in the clinical trial will be treated with this dose. This is termed the phase II part of the trial. The object of the trial is to find out what effects, good and/or bad, the combination of vorinostat, rituximab, cyclophosphamide, etoposide and prednisone will have on you and your lymphoma.
Some patients with multiple myeloma or lymphoma will need treatment with high dose chemotherapy to treat their condition. This potent treatment will kill many of the blood-forming cells in the bone marrow. The patient will therefore need these blood-forming cells replaced after the chemotherapy treatment. This is done by collecting some of teh patients own blood-forming stem cells before chemotherapy, storing them and then infusing them into the patient after chemotherapy (in the same way as a blood transfusion is given). The stem cells will then make their way unto the bone marrow and re-populate it. Having stem cells collected and returned later is called an "Autologous Transplant". In most patients these blood-forming stem cells (which normally live in the bone marrow) are "mobilized" into the blood stream where they are then collected by a process called apheresis (a bit like donating blood). This process of mobilization is not always successful. In this study patients who did not collect enough stem cells in a previous cell collection attempt to have an autologous stem cell transplant will participate. Patients will be mobilized with G-CSF (current standard treatment to mobilize stem cells) and the effect of adding AMD3100 to G-CSF will be studied by comparing outcomes in patients who get G-CDF with placebo (non-active substance which looks like AMD3100) to patients who get G-CSF with AMD3100. AMD3100 is a member of a new class of medications called "chemokine inhibitors". The drug triggers the movement of stem cells out of the bone marrow into the blood stream. In previous studies with healthy volunteers and cancer patients, when AMD3100 and G-CSF were used in combination, a greater number of stem cells were mobilized into the blood stream than by using g-CSF alone. The purposes of this study are to measure how many stem cells can be collected, the number of days to collect those cells and the safety of a mobilization regimen of AMD3100 with G-CSF compared to G-CSF with placebo. If enough cells are collected to have a transplant, the study will also evaluate how well the cells grow when transplanted.
The purpose of this study is to evaluate three things. The first being whether azacitidine is absorbed in the body at the same rate or proportion for different concentrations. The second is to determine the effect renal impairment has or does not have on the absorption of azacitidine. The third is to determine if azacitidine is safe and well tolerated in patients with renal function impairment.
The purpose of this study is to determine if we can prevent Epstein Barr Virus lymphomas by the monthly administration of an (antibody) protein against B lymphocytes called Rituximab. Although this medicine has been approved by the Food and Drug Administration to treat patients with other types of lymphomas, and has been used to treat a small number of patients with EBV lymphomas and other types of B-cell leukemias, it has not been approved to try and prevent EBV-lymphomas. Use of Rituximab to try to prevent EBV-lymphomas is therefore experimental.
You may have a type of cancer associated with "antineuronal antibodies" in your blood. Antibodies are substances made by the immune system. They are used by the body to fight infections and other diseases. Antineuronal antibodies are antibodies that react with nerve cells but they also react with some tumors. We believe that the immune system makes these antibodies to fight the cancer. In some patients with these antibodies, the tumor is smaller than in patients who have no antibodies. Sometimes, with a very strong antibody test, patients may develop neurologic problems such as weakness, numbness or memory loss. One purpose of this study is to determine if a patient with cancer and a positive antineuronal antibody blood test has a smaller tumor and responds better to treatment than a patient with cancer and a negative test. Another purpose of this study is to determine whether patients with a positive antibody test develop neurologic problems such as weakness, numbness or memory loss. We will measure your blood for several different kinds of antibodies in addition to antineuronal antibodies to determine if the presence of antibodies predicts "prognosis", i.e. smaller tumor and better response to treatment, or predicts the development of neurologic problems. No tissue samples are required for this study. However, if tissue or sputum is obtained by your oncologist for diagnostic purposes, we will ask your doctors or the pathology department to provide us with samples of these specimens. This will not involve any additional surgery or discomfort to you.
Results to date of umbilical cord blood transplantation in adult and fully mature adolescent patients are inferior to what is seen in children, due to a lower stem cell dosage in adults and a more toxic conditioning regimen. This phase 1 protocol will use a potentially less toxic bone marrow conditioning regimen, followed by infusion of a combined umbilical cord blood graft that will provide the patient with a higher stem cell dose than can be given with a single umbilical cord blood infusion. The subjects will be conditioned with a total body irradiation (TBI) 13.5 Gy and fludarabine. Following conditioning, up to two unrelated, partially matched umbilical cord blood grafts will be infused that will provide a minimum nucleated cell dose of 3 x 10e7/kg . The primary objective of this study is to measure the frequency of treatment-related toxicity and engraftment.
The purpose of this study is to collect information on the long-term side effects of treatment for Hodgkin Lymphoma. We hope to study about 500-800 survivors of Hodgkin Lymphoma. We plan to use the findings from this study to better understand Hodgkin Lymphoma survivors' health and quality of life.
The central hypothesis of this study is that use of a less toxic chemotherapy preparative regimen for allogeneic hematopoietic stem cell transplantation in combination with T cell depletion with alemtuzumab for patients with high risk hematologic malignancies will allow effective control of disease and improved disease free and overall survival compared with historical expectations. Specifically, the objectives are to estimate toxicity, disease free, progression free, event free, and overall survival rates in patients treated with alemtuzumab T cell depleted, reduced intensity preparative regimen followed by allogeneic hematopoietic transplantation; evaluate immune recovery following this reduced intensity allogeneic immunotherapy; develop an in vitro assay to allow patient individualized targeted dosing.
The purpose of this study is to compare the effects (good and bad) of the medication basiliximab in combination with cyclosporine with cyclosporine alone for the prevention of graft-versus-host disease. This research is being done because there is no completely safe and effective prevention for graft-versus-host disease. It is known that cyclosporine helps with GVHD but we would like to know if the addition of basiliximab will decrease the incidence and/or severity of GVHD after a transplant known as nonmyeloablative ("mini" transplant).