View clinical trials related to Leukemia.
Filter by:This is a phase II, single-center study to evaluate the efficacy of a novel cytoreductive regimen followed by CD34+E- selected T cell depleted allogeneic stem cell (or soybean agglutinated and E-rosetted BM) transplant as treatment for patients with acute and chronic leukemias, lymphoma and myelodysplstic syndrome/PNH. The impact of the change in conditioning regimen and use of CD34-selected T cell depleted PBSCs on transplanted related morbidity and mortality and disease free survival will be assessed.
A dose-escalation study to identify the dose-limiting toxicity (DLT) and maximum tolerated dose (MTD), defined as the highest dose that can safely be given to a participant and establish the safest dose based on the highest tolerated dose for clinical testing.
This study is designed to determine the number of donor lymphocytes that can be given to recipients of haploidentical stem cell transplants after depletion of recipient-reactive T lymphocytes by ex-vivo treatment with a fixed dose of RFT5-dgA immunotoxin, and will result in a rate of Grade III/IV GVHD of < / = 25%, to analyze immune reconstitution in these patients, and to measure their overall and disease free survival, at 100 days and at 1 year.
Patients on this study have a type of lymph gland cancer called non-Hodgkin Lymphoma, Acute Lymphocytic Leukemia, or chronic Lymphocytic Leukemia (these diseases will be referred to as "Lymphoma" or "Leukemia"). Their Lymphoma or Leukemia has come back or has not gone away after treatment (including the best treatment known for these cancers). This research study is a gene transfer study using special immune cells. The body has different ways of fighting infection and disease. No one way seems perfect for fighting cancers. This research study combines two different ways of fighting disease, antibodies and T cells, hoping that they will work together. Antibodies are types of proteins that protect the body from bacterial and other diseases. T cells, also called T lymphocytes, are special infection-fighting blood cells that can kill other cells including tumor cells. Both antibodies and T cells have been used to treat patients with cancers; they have shown promise, but have not been strong enough to cure most patients. T lymphocytes can kill tumor cells but there normally are not enough of them to kill all the tumor cells. Some researchers have taken T cells from a person's blood, grown more of them in the laboratory and then given them back to the person. The antibody used in this study is called anti-CD19. It first came from mice that have developed immunity to human lymphoma. This antibody sticks to cancer cells because of a substance on the outside of these cells called CD19. CD19 antibodies have been used to treat people with lymphoma and Leukemia. For this study anti-CD19 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. In the laboratory, investigators have also found that T cells work better if they also put a protein that stimulates T cells called CD28. Investigators hope that adding the CD28 might also make the cells last for a longer time in the body. These CD19 chimeric receptor T cells with C28 T cells are investigational products not approved by the Food and Drug Administration. The purpose of this study is to find the biggest dose of chimeric T cells that is safe, to see how the T cell with this sort of chimeric receptor lasts, to learn what the side effects are and to see whether this therapy might help people with lymphoma or leukemia.
The purpose of this study is to test the safety and effectiveness of combining a drug known as Lovastatin to the chemotherapy drug cytarabine. Lovastatin is currently used to lower blood cholesterol levels and lab data suggests that it increases the anti-leukemia activity of cytarabine. This research is being done because high doses of cytarabine induce remissions in only about 25% of patients with acute myeloid leukemia.
The purpose of this research study is:(1) to determine if high doses of chemotherapy without total body irradiation can allow selected stem cells to take and grow,(2) to determine if selected stem cells from the blood or marrow can take and not cause a complication called graft-versus-host disease (GvHD) and (3) to evaluate the side effects of the combination of chemotherapy drugs used for these transplants. In the last 10 years we have developed chemotherapy combinations to be used for this T-cell depleted transplant protocol. By using three chemotherapy drugs (IV busulfan, melphalan and fludarabine), we hope to have a good chemotherapy combination to kill cancer cells, and to make the graft take, without the side effects of total body irradiation. The chemotherapy drugs to be tested in this protocol are busulfan, melphalan and fludarabine, all of which have been used successfully for stem cell transplantation, but not given together as in this specific regimen. This is what is being tested in this study. Our initial trials in the 1980's with T-cell depleted transplants showed less GvHD, but the overall results of the transplants were not better. The reason for this was that the stem cells did not take and engraft in 15% of our adult patients. This failure of the stem cells to take can leave patients without bone marrow or blood cells necessary for life. Most stem cell transplants were done using bone marrow (BMA) obtained from the donors. However, if we give a medication called G-CSF by shots to the donor, we can collect peripheral blood stem cells (PBSC) and use them for transplant. The advantage of this approach is that we can collect 2-20 times more stem cells than that obtained from the marrow. It has been proven that a larger number of stem cells in the graft make it more difficult for the patient to reject the stem cells. Some donors may be too small to provide peripheral blood stem cells or they may not want to take G-CSF shots. In these cases the donors will have their marrow collected in the operating room under general anesthesia. Stem cell transplants can lead to a condition known as acute graft-versus-host disease or GvHD. This disease is caused by an assault by certain cells in the marrow or blood (T-cells) of the donor (graft) against your body (the host). These T-cells see your body as foreign and attack it. The disease causes a skin rash, liver disease, and diarrhea. Methods were developed at this institution to prevent GvHD. These methods take out most of the T-cells (responsible for GvHD) from the marrow or blood stem cells before transplant. This is called "T-cell depletion" or "stem cell selection". In this hospital, we use two types of methods of T-cell depletion: one method is used with peripheral blood stem cells and one for bone marrow. Both these techniques have been successful in preventing both acute and chronic GvHD. You will receive a T-cell depleted stem cell transplant.
This study will assess the feasibility of utilizing a reduced intensity conditioning regimen, in the setting of haploidentical transplantation, for patients with recurrent acute lymphoblastic leukemia (ALL), AML and high risk or refractory solid tumors. In addition, the feasibility and safety of administering post-transplant NK cell infusions will be evaluated. Data obtained from this study will help determine the efficacy of allogeneic HSCT in the treatment of pediatric sarcomas and add to the small body of literature utilizing haploidentical HSCT to treat acute leukemia in pediatric patients. This study will also further elucidate the role of NK cells in mediating a graft vs. tumor effect in allogeneic HSCT. The main benefit to society is that this study will explore a novel therapy for children with highly refractory cancer who are felt to be incurable with conventional approaches. If feasibility is demonstrated, and there is evidence of anti-tumor activity, then this will open up a new area of clinical research to better define the efficacy of this approach for specific childhood malignancies.
The purpose of this study is to better understand the genetic causes of Hodgkin's disease (a kind of lymphoma) and non-Hodgkin's lymphoma, as well as multiple myeloma, leukemia, and related diseases. The doctors have identified the patient because 1) they have had a lymphoproliferative disorder such as lymphoma, leukemia, or multiple myeloma, and have a family member with one of these disorders or 2) they are a member of a family with a lymphoproliferative disorder, including Hodgkin's disease and/or, non-Hodgkin's lymphoma or a second cancer after Hodgkin's disease.
This study aims to learn about the needs and feelings of women who are infertile. Being infertile means not being able to have a child without the help of a third party. There are other options for building a family. The researchers are interested in the participants' thoughts about these options and want to learn about the experiences of infertile women due to cancer treatment as well as women who are infertile due to other causes. The researchers hope that what they learn will allow them to better care for infertile women in the future.
The drug that you are taking for your cancer, imatinib (GleevecTM), has recently been shown to have some new types of side effects. In some people, imatinib can affect how bones are made. The purpose of this study is to find out if imatinib is causing these side effects in you. We can check how your bones form by testing your blood and urine. We can also check your bone strength by doing a special X-ray of your bone called bone density (or DEXA scan).