View clinical trials related to Lymphoproliferative Disorders.
Filter by:Background: The drug Nivolumab has been approved to treat some cancers. Researchers want to see if it can slow the growth of other cancers. They want to study its effects on cancers that may have not responded to chemotherapy or other treatments. Objectives: To see if Nivolumab slows the growth of some types of cancer or stops them from getting worse. To test the safety of the drug. Eligibility: People 12 and older who have Epstein-Barr Virus (EBV)-positive lymphoproliferative disorders or EBV-positive non-Hodgkin lymphomas with no standard therapy Design: Participants will be screened with: Medical history Physical exam Blood and urine tests CAT scan of the chest, abdomen, and pelvis Tumor and bone marrow biopsies (sample taken) Magnetic resonance imaging scan of the brain Lumbar puncture (also known as spinal tap) Positron emission tomography/computed tomography scan with a radioactive tracer Every 2 weeks, participants will get Nivolumab by vein over about 1 hour. They will also have: Physical exam Blood and pregnancy tests Review of side effects and medications During the study, participants will repeat most of the screening tests. They may also have other biopsies. After stopping treatment, participants will have a visit every 3 months for 1 year. Then they will have a visit every 6 months for years 2-5, and then once a year. They will have a physical exam and blood tests.
This is an open-label, multi-center, prospective, single arm phase 2 trial of the combination of bendamustine and rituximab in patients with PTLD, monomorphic cluster of differentiation antigen 20(CD20) positive DLBCL. The investigators want to investigate the efficacy and safety of the combination of bendamustine and rituximab in patients with previously untreated PTLD, monomorphic CD20 (+) diffuse large B-cell lymphoma.
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 that protect the body from disease caused by bacteria or toxic substances. Antibodies work by binding those bacteria 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. Both antibodies and T cells have been used to treat patients with cancers. They both have shown promise, but neither alone has been sufficient to cure most patients. This study is designed to combine both T cells and antibodies to create a more effective treatment called autologous T lymphocyte chimeric antigen receptor cells targeted against the CD30 antigen (ATLCAR.CD30) administration. In previous studies, it has been shown that a new gene can be put into T cells that will increase their ability to recognize and kill cancer cells. The new gene that is put in the T cells in this study makes an antibody called anti-CD30. This antibody sticks to lymphoma cells because of a substance on the outside of the cells called CD30. Anti-CD30 antibodies have been used to treat people with lymphoma, but have 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 CD30 chimeric (combination) receptor-activated T cells seem to kill some of the tumor, but they do not last very long in the body and so their chances of fighting the cancer are unknown. The purpose of this research study is to establish a safe dose of ATLCAR.CD30 cells to infuse after lymphodepleting chemotherapy and to estimate the number patients whose cancer does not progress for two years after ATLCAR.CD30 administration. This study will also look at other effects of ATLCAR.CD30 cells, including their effect on the patient's cancer.
This study evaluates the safety and efficacy of EBV-specific T-cell lines to treat patients suffering from high EBV viral titers not responding to standard of care therapies and to treat EBV-related lymphoma. The study will recruit 6 patients to receive autologous T cells or a T cell line derived from the patient's allogeneic donor (in the case of stem cell transplant recipients), and 6 patients to receive a T-cell line prepared from a matched or partially matched related donor.
Background: Allogeneic blood or marrow transplant is when stem cells are taken from one person s blood or bone marrow and given to another person. Researchers think this may help people with immune system problems. Objective: To see if allogeneic blood or bone marrow transplant is safe and effective in treating people with primary immunodeficiencies. Eligibility: Donors: Healthy people ages 4 or older Recipients: People ages 4-75 with a primary immunodeficiency that may be treated with allogeneic blood or marrow transplant Design: Participants will be screened with medical history, physical exam, and blood tests. Participants will have urine tests, EKG, and chest x-ray. Donors will have: Bone marrow harvest: With anesthesia, marrow is taken by a needle in the hipbone. OR Blood collection: They will have several drug injections over 5-7 days. Blood is taken by IV in one arm, circulates through a machine to remove stem cells, and returned by IV in the other arm. Possible vein assessment or pre-anesthesia evaluation Recipients will have: Lung test, heart tests, radiology scans, CT scans, and dental exam Possible tissue biopsies or lumbar puncture Bone marrow and a small piece of bone removed by needle in the hipbone. Chemotherapy 1-2 weeks before transplant day Donor stem cell donation through a catheter put into a vein in the chest or neck Several-week hospital stay. They will take medications and may need blood transfusions and additional procedures. After discharge, recipients will: Remain near the clinic for about 3 months. They will have weekly visits and may require hospital readmission. Have multiple follow-up visits to the clinic in the first 6 months, and less frequently for at least 5 years.
In many countries, numerous steps are taken to minimize the risk of infection from transfused blood products. Typically, blood banking organisations will screen for an array of infectious pathogens as part of their quality control protocol. While transmission of these tested agents via transfusion has become exceedingly rare, the risk of transfusion-transmitted infections for which testing is not currently performed continues to be a concern. Among these untested infectious agents is Epstein-Barr virus (EBV, also known as human herpesvirus-4). Most notably, infection with this virus in transplant recipients can give rise to a malignant disorder called post-transplant lymphoproliferative disease (PTLD), a life-threatening complication which is due to the uncontrolled expansion of EBV-infected cells. It is also associated with other complications such as hepatitis, hemophagocytic syndrome, etc. in transplant population. It is recognised that EBV infection can occurred in transfused immune suppressed graft recipients but the origin of the viral infection is still a matter of debate. It is a known fact that the EBV already present in the recipient's blood can undergo reactivation due to immune suppression. However, because it is known to occur more frequently in patients who are EBV-seronegative at the time of transplant, it is also accepted that primary infection contracted via an infected graft can be a source of virus. The question we are seeking to answer is whether immune suppressed graft recipients can acquire primary EBV infection via transfusion of blood products. EBV is present in the blood of most adults and cases of EBV transfusion-related infection have been reported. Transplant populations are generally transfused with very large volumes of blood products and our recent pilot study supports the possibility that transfusion-related EBV infection can be transmitted to pediatric hematopoietic stem cell (HSCT) recipients (Trottier et al, 2012). The aim of this study is to analyse the risk of EBV transmission through blood product transfusion in pediatric allogeneic HSCT patients.
This study gathers health information for the Project: Every Child for younger patients with cancer. Gathering health information over time from younger patients with cancer may help doctors find better methods of treatment and on-going care.
The subject has a type of cancer or lymph gland disease associated with a virus called Epstein Barr Virus (EBV), which has come back, is at risk of coming back, or has not gone away after standard treatments. This research study uses special immune system cells called LMP, BARF-1 and EBNA1- specific cytotoxic T lymphocytes (MABEL CTLs). Some patients with Lymphoma (such as Hodgkin (HD) or non-Hodgkin Lymphoma (NHL)), T/NK-lymphoproliferative disease, or CAEBV, or solid tumors such as nasopharyngeal carcinoma (NPC), smooth muscle tumors, and leiomyosarcomas show signs of a virus called EBV before or at the time of their diagnosis. EBV causes mononucleosis or glandular fever ("mono" or the "kissing disease"). EBV is found in the cancer cells of up to half the patients with HD and NHL, suggesting that it may play a role in causing Lymphoma. The cancer cells (in lymphoma) and some immune system cells (in CAEBV) infected by EBV are able to hide from the body's immune system and escape destruction. EBV is also found in the majority of NPC and smooth muscle tumors, and some leiomyosarcomas. We want to see if special white blood cells (MABEL CTLs) that have been trained to kill EBV infected cells can survive in your blood and affect the tumor. In previous studies, EBV CTLs were generated from the blood of the patient, which was often difficult if the patient had recently received chemotherapy. Also, it took up to 1-2 months to make the cells, which is not practical when a patient needs more urgent treatment. To address these issues, the MABEL CTLs were made in the lab in a simpler, faster, and safer way. The MABEL CTLs will still see LMP proteins but also two other EBV proteins called EBNA-1 and BARF. To ensure these cells are available for use in patients in urgent clinical need, we have generated MABEL CTLs from the blood of healthy donors and created a bank of these cells, which are frozen until ready for use. We have previously successfully used frozen T cells from healthy donors to treat EBV lymphoma and virus infections and we now have improved our production method to make it faster. In this study, we want to find out if we can use banked MABEL CTLs to treat HD, NHL, T/NK-lymphoproliferative disease, CAEBV, NPC, smooth muscle tumors or leiomyosarcoma. We will search the bank to find a MABEL CTL line that is a partial match with the subject. MABEL CTLs are investigational and not approved by the Food and Drug Administration.
This study hypothesizes that a reduced intensity immunosuppressive preparative regimen will establish engraftment of donor hematopoietic cells with acceptable early and delayed toxicity in patients with immune function disorders. A regimen that maximizes host immune suppression is expected to reduce graft rejection and optimize donor cell engraftment.
The purpose of this prospective study is evaluate the best dose of busulfan for each patient undergoing Haematopoietic Stem Cell Transplantation