Active clinical trials for "Leukemia, Lymphoid"

Blood cancers occur when the molecules that control normal cell growth are damaged. Many of these changes can be detected by directly examining parts of the cancer or cells in blood. Several alterations that occur repeatedly in certain types of blood cancers have already been identified, and these discoveries have led to the development of new drugs that target those alterations. More remain to be discovered. Some of these abnormalities include alterations in genes. Genes are the part of cells that contain the instructions which tell the investigators bodies how to grow and work, and determine physical characteristics such as hair and eye color. Genes are composed of DNA letters that spell out these instructions. Studies of the DNA molecules that make up the genes are called "molecular" analyses. Molecular analyses are ways of reading the DNA letters to identify errors in genes that may contribute to an increased risk of cancer or to the behavior of the cancer cells. Some changes in genes occur only in cancer cells. Others occur in the genes that are passed from parent to child. This research study will examine both kinds of genes. The best way to find these genes is to study large numbers of people. The investigators expect that as many 1000 individuals will enroll in this study. This research study is trying to help doctors and scientists understand why cancer occurs and to develop ways to better treat and prevent it. To participate in this study the participant must have cancer now, had it in the past, or are at risk of developing cancer. The participant will not undergo tests or procedures that are not required as part of their routine clinical care. The investigators will ask the participant to provide an additional sample from tissue that is obtained for their clinical care including blood, bone marrow, or tissue sample. The investigators will also ask for a gentle scrape of the inside of their cheek, mouthwash or a skin sample to obtain their germline DNA

This study is a treatment protocol with blinatumomab for infants under 1 year old who are diagnosed with acute lymphoblastic leukemia with a specific unfavorable genetic alteration. The purpose of the study is to improve the outcome of this disease in infants.

This study is a multicenter, prospective, interventional clinical trial aimed at recruiting relapsed/refractory Ph-ALL patients at multiple stem cell transplantation centers, including the Stem Cell Transplantation Center of the Chinese Academy of Medical Sciences Hematology Hospital. The anticipated enrollment is 42 subjects. The enrolled patients are planned to receive a treatment regimen of chidamide in combination with venetoclax and obinutuzumab. Patients who achieve remission will undergo allogeneic stem cell transplantation, followed by continued oral maintenance therapy with chidamide for one year post-transplantation based on the disease condition.

The innovation of this protocol is the risk-adapted choice of therapy and the use of a combination of chemotherapy with immunotherapy and hematopoietic stem cell transplantation for patients with risk factors. we have proposed a two-stage stratification into risk groups: Initially: Standard risk: patients with no rearrangement of the KMT2A gene. Intermediate risk: patients with rearrangement of the KMT2A gene without damage to the central nervous system. High risk: patients with rearrangement of the KMT2A gene with lesions of the central nervous system. According to the results of induction therapy: The high-risk group includes patients from the standard risk group with an MRD level of more than 0.1% after the induction course and from the intermediate risk group with MRD-positive (PCR) after HR1 block. The allocation of children in the first year of life without the rearranged KMT2A gene into a separate group seems to be logical, since the prognosis in this group is better than in children with the rearranged KMT2A gene. In this protocol, non-intensive therapy with consolidations and maintenance therapy remains for those who achieve a low MRD level (less than 0.1%) after a course of induction. The rest of the patients move into a high-risk group: they receive blinatumomab and HSCT. The concept of therapy for patients at intermediate risk is based on the rate at which MRD-negativity is achieved: standard consolidation and maintenance therapy for those who became MRD-negative at the end of induction, "block" chemotherapy for those who were positive at the end of induction, but achieved negativity after HR1 block, blinatumomab with HSCT for those who have preserved the MRD after the HR1 block. For high-risk patients, a combination of immunotherapy (blinatumomab - a bispecific CD3 / CD19 T-cell activator) and HSCT in the first remission was chosen.

PBLTT52CAR19 modified T cells are allogenic engineered human T cells (defined as TT52CAR19 +TCRαβ-) prepared for the treatment of CD19+ B cell leukaemia. The cells are from healthy adult volunteer donors and are not HLA-matched. They have been transduced to express and anti-CD19 chimeric antigen receptor (CAR19) using a lentiviral vector that also incorporates CRISPR guides for genome editing of CD52 and TRAC loci in the presence of transiently provided Cas9. Recognition by TT52CAR19 T cells mediates eradication of CD19+ leukaemia and other CD19+ B cells through T cell mediated cytotoxicity. This study aims to apply PBLTT52CAR19 T cells to secure molecular remission in children with relapsed/refractory B-ALL ahead of programmed allogeneic stem cell transplantation. The cells are to be used in a time-limited manner for their anti-leukaemia effects and then depleted by standard pre- transplant conditioning.

Brief Overview: Children and adolescents diagnosed with cancer will experience problems with learning, memory and attention during and after completing their cancer therapy. There are many factors that contribute to this problem, but investigators have recently identified that chemotherapy agents used in treating Acute Lymphoblastic Leukemia (ALL) may disrupt normal brain development. A novel device has been developed that may help correct this disruption. Direct Current Stimulation (DCS) uses a very low level of constant electrical current to stimulate specific parts of the brain. It has been used in patients with stroke to great benefit. Our study at St. Jude Children's Research Hospital is designed to see if this technique will benefit survivors of childhood cancer. Specifically, investigators wish to see if stimulating one part of the brain gives a greater benefit than stimulating another part of the brain. Primary Objective Evaluate the feasibility of conducting repeated on-site Transcranial Direct Current Stimulation (tDCS) in children who are long-term survivors of Secondary Objectives To estimate the potential efficacy for powering a future larger study using tDCS to improve cognitive performance in children by suppressing over connected neural hubs in long-term survivors of childhood ALL. To compare the performance of anodal stimulation of the frontal lobe to cathodal suppression of the superior temporal lobe on cognitive performance.

The purpose of this study is to evaluate the long-term safety and efficacy of UCART19 administration to patients with advanced lymphoid leukemia.

This randomized phase I trial studies the side effects of vaccine therapy in preventing cytomegalovirus (CMV) infection in patients with hematological malignancies undergoing donor stem cell transplant. Vaccines made from a tetanus-CMV peptide or antigen may help the body build an effective immune response and prevent or delay the recurrence of CMV infection in patients undergoing donor stem cell transplant for hematological malignancies.

This randomized phase III trial studies compliance to a mercaptopurine treatment intervention compared to standard of care in younger patients with acute lymphoblastic leukemia that has had a decrease in or disappearance of signs and symptoms of cancer (remission). Assessing ways to help patients who have acute lymphoblastic leukemia to take their medications as prescribed may help them in taking their medications more consistently and may improve treatment outcomes.

This phase II trial studies how well ruxolitinib phosphate works in reducing fatigue in patients with chronic lymphocytic leukemia. Ruxolitinib phosphate may stop the growth of cancer cells by blocking a protein called Janus kinase (JAK) that is needed for cell growth and may also help control fatigue, decrease the size of lymph nodes and/or lower the number of chronic lymphocytic leukemia cells in the blood.