View clinical trials related to Non-Hodgkin Lymphoma.
Filter by:Patients have a type of blood cell disorder that is very hard to cure. We are now suggesting a treatment that might help patients live longer without disease than other treatment plans would. This treatment is known as a stem cell transplant. We believe this may help patients as it allows us to give much stronger doses of drugs and radiation to kill the diseased cells than we could give without the transplant. We also think that the healthy cells may help fight any diseased cells left after the transplant. Stem Cells are special "mother" cells that are found in the bone marrow (the spongy tissue inside bones), although some are also found in the bloodstream (peripheral blood). As they grow, they become either white blood cells which fight infection, red blood cells which carry oxygen and remove waste products from the organs and tissues or platelets, which enable the blood to clot. For the transplant to take place, we will collect these stem cells from a "donor" (a person who agrees to donate these cells) and give them to recipient. Patients do not have a sibling that is a perfect match, so the stem cells will come from a donor who is the best match available. This person may be a close relative or an unrelated person whose stem cells best "matches" the patients, and who agrees to donate stem cells. Before the transplant, two very strong drugs plus total body irradiation will be given to the patient (pre-conditioning). This treatment will kill most of the blood-forming cells in the bone marrow. We will then give the patient the healthy stem cells. Once these healthy stem cells are in the bloodstream they will move to the bone marrow (graft) and begin producing blood cells that will eventually mature into healthy red blood cells, white blood cells and platelets. This research study will also use CAMPATH-1H as a pre-treatment. CAMPATH-1H is an antibody against certain types of blood cells. CAMPATH-1H is important because it stays active in the body for a long time after infusion, which means it may work longer at preventing GvHD symptoms. The stem cell transplant described above is considered to be "standard" treatment. We would like to collect additional blood as described below in order to evaluate how the immune system is recovering. We are asking permission to draw blood from the patient so that we can measure the number of certain blood cells called T regulatory cells. T regulatory cells are special immune cells that can control or regulate the body's immune response. We want to determine whether T regulatory cells are important participants in graft versus host disease (GVHD), infection and relapse. In GVHD, certain cells from the donated marrow or blood (the graft) attack the body of the transplant patient (the host). GVHD can affect many different parts of the body. The skin, eyes, stomach and intestines are affected most often. GVHD can range from mild to life-threatening. We do not know whether T regulatory cells can modify these conditions. We want to measure these T regulatory cells and learn if these cells do influence these conditions. If we learn that T regulatory cells do affect these conditions, then it may be possible to modify these cells for the benefit of transplant patients.
This phase I trial studies the side effects and best dose of veliparib when given together with irinotecan hydrochloride in treating patients with cancer that has spread to other parts of the body or that cannot be removed by surgery. Irinotecan hydrochloride can kill cancer cells by damaging the deoxyribonucleic acid (DNA) that is needed for cancer cell survival and growth. Veliparib may block proteins that repair the damaged DNA and may help irinotecan hydrochloride to kill more tumor cells. Giving irinotecan hydrochloride together with veliparib may kill more cancer cells.
The goals of the study are (Phase I) to determine the appropriate dose for Clofarabine with Busulfan as a full-intensity conditioning (Clo/BU4 regimen) prior to transplant and then (Phase II) to investigate the safety and effectiveness of this regimen as a conditioning for stem cell transplant in the treatment of aggressive hematologic malignancies in subjects where more conventional approaches are failing.
Patients are being asked to participate in this study because treatment for their disease requires a stem cell transplant (SCT). Stem cells are the source of normal blood cells found in the bone marrow and lead to recovery of blood counts after bone marrow transplantation. With stem cell transplants, regardless of whether the donor is a full match to the patient or not, there is a risk of developing graft-versus-host disease (GVHD). GVHD is a serious and sometimes fatal side effect of SCT. GVHD occurs when the new donor stem cells (graft) recognizes that the body tissues of the patient (host) are different from those of the donor. When this happens, cells in the graft may attack the host organs. How much this happens and how severe the GVHD is depends on many things, including how different the donors cells are, the strength of the drugs given in preparation for the transplant, the quality of transplanted cells and the age of the person receiving the transplant. Typically, acute GVHD occurs in the first 100 days following transplant, while chronic GVHD occurs after day 100. Acute GVHD most often involves the skin, where it can cause anywhere from a mild rash to complete removal of skin; liver, where it can anywhere from a rise in liver function tests to liver failure; and the gut, where it can cause anywhere from mild diarrhea to profuse, life-threatening diarrhea. Most patients who develop GVHD experience a mild to moderate form, but some patients develop the severe, life-threatening form. Previous studies have shown that patients who receive SCT's can have a lower number of special T cells in their blood, called regulatory T cells, than people who have not received stem cell transplants. When regulatory T cells are low, there appears to be an increased rate of severe, acute GVHD. A drug known as IL-2 (Proleukin) has been shown to increase the number of regulatory T cells in patients following stem cell transplant, and in this study investigators plan to give low dose IL-2 after transplant. This study is called a phase II study because its major purpose is to find out whether using a low-dose of IL-2 will be effective in preventing acute GVHD. Other important purposes are to find out if this treatment helps the patient's immune system recover regulatory T cells faster after the transplant. This study will assess the safety and toxicity of low-dose IL-2 given to patients after transplantation and determine whether this drug is helpful in preventing GVHD.
The promising activity of Bortezomib as single agent in low grade lymphoma patients in small studies has led to a number of larger multicenter trials with Bortezomib in combination with Rituximab in mantle-cell lymphoma, follicular lymphoma and marginal zone lymphoma.
The primary purpose of this open-label study is to investigate the interaction of ketoconazole, a liver enzyme inhibitor, on oral LBH589 in adult patients with advanced solid tumors. The extension phase of the study will evaluate the safety and efficacy of LBH589 in patients with advanced solid tumors.
This study has two parts (A and B). The primary purpose of Part A is to find the maximum tolerated dose is for an experimental drug called AZD4877 based on the side effects experienced by patients that receive AZD4877 on a twice a week basis. For Part B, an additional 20 patients will be treated at the maximum dose identified in Part A. AZD4877 is an Eg5 or Kinesin Spindle Protein inhibitor that interferes with tumor cell division leading to tumor growth
Participants with non-Hodgkin lymphoma (NHL) or Hodgkin disease (HD) will be assigned to one of 2 arms based on the immunophenotype of their lymphoma. (A)Participants with CD20(-) lymphoma will undergo mobilization with granulocyte colony-stimulating factor (G-CSF) and plerixafor. (B) Participants with CD20(+) lymphomas will undergo mobilization with rituximab, G-CSF, and plerixafor. They will receive a weekly dose of rituximab beginning 1 week prior to, and continuing until 2 weeks after, the first dose of G-CSF. Participants in both groups will receive G-CSF twice daily for 4 days. In the evening on Day 4, a dose of plerixafor will be administered. Apheresis will be initiated the next morning. Participants will continue to receive G-CSF twice daily and to receive the evening dose of plerixafor followed by apheresis the next morning for up to a total of 4 aphereses or until ≥5*10^6 CD34+ cells/kg are collected. Participants who are transplanted will be monitored for the time to polymorphonuclear leukocytes (PMN), platelets (PLT), and lymphocyte engraftment. Follow-up assessments will be done at 100 days, and 6 and 12 months post-transplantation.
The purpose of this study is to determine whether a specific subtype of lymphoma responds optimally to treatment with rituximab and chemotherapy.
This study investigates whether the prophylactic use of moxifloxacin during high-dose chemotherapy followed by autologous stem cell transplantation reduces the incidence of clinically significant bacteremia. Further investigations include time to occurrence of fever, duration of fever, overall survival and antibiotic sensitivity of blood isolates.