View clinical trials related to Acute Lymphoblastic Leukemia.
Filter by:Asparaginase is an important drug in the treatment of childhood leukemia. One of the rare but severe side effects to the treatment is thrombosis in or outside the central nervous system. The aim of this study is to investigate and describe the influence on the coagulation parameters during prolonged treatment with asparaginase. Hopefully this knowledge will help to foresee the risk of thrombosis and thus making it possible to prevent these.
To study the genomics with cell cycle and lymphocyte differentiation in disease, remission and relapse of childhood acute lymphoblastic leukemia. Then correlate these data with age, white cell count, cytogenetic changes, response to the chemotherapy and prognosis.
Acute lymphoblastic leukemia (ALL) is not a single disease, but a composite of heterogeneous subgroup. Accordingly, more sophisticated classification in ALL is essential to achieve further improvement of treatment outcomes. However, only a few genetic markers are revealed to have significant prognostic implications in ALL patients. The current study is designed to stratify the ALL patients according to their prognosis and to predict their outcomes by a pharmacogenetic approach. A predictive model will be generated from 130 genotypes in adult ALL patients diagnosed at the Samsung Medical Center (SMC), Sungkyunkwan University School of Medicine, Seoul,Korea between 1994 and 2008. The validation of the predictive model will be performed using an independent external cohort of ALL patients. 1. Definition of the cohort: two hundred ALL patients from the SMC as a test set, another 100 patients from the SMC as a first validation set, and another 150 independent external patients as second external validation set. DNAs will be extracted and stored from patients' samples collected at the time of diagnosis. 2. In the test set, genotypes will be determined using a MALDI-TOF based platform (Sequenom, San Diego, CA, USA) for 130 SNPs of the candidate genes involved in DNA repair pathway, drug metabolism/transport pathway and folate metabolism pathway. 3. Bioinformatic analyses will be performed to identify around 13 genotypes (10%) having strongest predictive significance out of these 130 SNPs in terms of their treatment outcomes, drug toxicity and prognosis in the test set. 4. These 13 genotypes will be validated in the first cohort of 100 ALL patients using a multivariate Cox's proportional hazard model. 5. The predictive model will be built up based on Cox's proportional hazard model derived from 13 candidate genotypes and clinical risk factors. 6. The predictive model based on pharmacogenetic information will be validated again in the second, independent external cohort of 150 ALL patients. Definite prognostic value was not established for genetic or molecular markers in acute lymphoblastic leukemia (ALL) except BCR/ABL fusion gene. The current study attempts to build up a predictive model based on single nucleotide polymorphisms (SNPs) with pharmacogenetic approach using 130 genotypes in the multiple candidate pathways such as DNA repair pathway, drug metabolism / transport pathway and folate metabolism pathway. The predictive model based on SNPs will be generated and validated with respect to treatment outcomes, drug toxicity and prognosis in adult ALL patients. The present study will demonstrate that: 1) Pharmacogenetic information derived from SNPs involved in the DNA repair pathway, drug metabolism/transport pathway and folate metabolism pathway, is helpful to predict the treatment outcomes, drug toxicity and prognosis in ALL patients; 2) Predictive model derived from pharmacogenetic information will be effective and reasonable approach to stratify ALL patients according to their clinical outcomes; 3) The SNP-based predictive model could be reasonably applied to the treatment of ALL patients, thus becoming a basis for further improvement of treatment outcome; 4) Finally, this project will enhance and facilitate the pharmacogenetic research in the hematology area, thus make the team to lead the pharmacogenetic research in the world.
This study will assess the pharmacokinetics of nilotinib in Ph+ CML pediatric patients that are newly diagnosed or resistant or intolerant to imatinib or dasatinib or refractory or relapsed Ph+ ALL compared to the adult populations. It will also evaluate safety and activity of nilotinib as secondary objectives.
Patients with refractory hematologic malignancies, including those who develop recurrent disease after allogeneic hematopoietic stem cell transplantation (HSCT) have a dismal prognosis. Historically, both regimen-related mortality and disease recurrence have been significant causes of treatment failure in this heavily pre-treated patient population. Novel therapeutic agents that target molecular signaling mechanisms and increase the sensitivity of leukemic cells to apoptosis may clearly play a role in this setting. This study hypothesizes that interrupting the SDF-1/CXCR4 axis using the selective CXCR4 antagonist plerixafor may be useful as a leukemic stem cell mobilizing agent for patients who are refractory to standard dose chemotherapy and in relapse after an allogeneic transplant. This hypothesis is based on the dependence of leukemia cells on MSCs for survival signals as described above and on the preclinical data that suggest increased efficacy by antileukemia agents when leukemia cells are separated from MSCs. In the present trial, the study proposes to add plerixafor to enhance the conditioning regimen cytotoxicity. At this time the goal is to determine the maximum tolerated dose (MTD) of plerixafor through the process of dose limiting toxicity (DLT) evaluation. Pharmacokinetic studies will be conducted. Additional studies will quantify and the content of leukemia cells and key regulatory and effector T cell populations in the bone marrow and blood before and after exposure to this medication. If the observed outcomes of this trial are promising, it could serve as a platform on which to study further use of plerixafor as a complimentary agent with conditioning as well as other chemotherapeutic regimens for patients with relapsed or refractory hematologic malignancies.
The purpose of this study is to evaluate if enteral docosahexaenoic acid (DHA) administration during the first three months of treatment reduces the deterioration of nutritional status, treatment toxicity and early mortality in children with acute lymphoblastic leukemia.
The primary goal of this study is to provide comprehensive and objective information on impairments of musculoskeletal health, sensory function, and fitness among a large group of childhood ALL survivors, and to define high risk groups by assessing treatment factors that contribute to impaired function. This study includes a direct, objective evaluation of musculoskeletal function, sensory capacity, fitness, and physical activity patterns among adults who were treated for childhood ALL at St. Jude Children's Research Hospital (SJCRH) between 1980 and 1999. Among 899 ALL survivors, all of whom are eligible for an institutionally funded clinical study of medical late effects, the study will recruit 364 to participate in our evaluations. The study will also recruit 364 individuals for a comparison group, frequency matching on race/ethnicity, age and gender.
This study is an investigational approach that uses immune cells, called "T cells", to kill leukemia. These T cells are removed from blood, modified in a laboratory, and then put back in the body. T cells fight infections and can also kill cancer cells in some cases. However, right now T cells are unable to kill the cancer cells. For this reason we will put one gene into the T cells that allows them to recognize and kill the leukemia cells. This gene will be put in the T cells by a weakened virus. The gene will produce proteins in the T cells that help the T cells recognize the leukemia cells and possibly kill them. The doctors have found that T cells modified in this way can cure an ALL-like cancer in mice. The main goals of this study is to determine the safety and appropriate dose of these modified T cells in patients with ALL. This will be done in a "clinical trial." The dose of modified T-cells will depend on if you have disease present in your bone marrow or not. The patient will also receive chemotherapy before the T cells. We will use normally chemotherapy that is used in patients with leukemia. The chemotherapy is given to reduce leukemia and to allow the T cells to live longer.
There is no curative therapy once acute leukemia patients relapse after transplant. Patients who develop clinically significant graft versus host disease (GVHD) have a lower rate of relapse than those who do not develop GVHD. We are initiating this study of post-transplant fast withdrawal of immunosuppression and donor lymphocyte infusions, with a goal of achieving full donor chimerism in children with hematologic malignancies. If our hypothesis that full donor chimerism results in leukemia-free survival is correct, using immune modulation to achieve full donor chimerism should decrease relapse rate and thus increase survival. The goal of this Phase II study is to identify if achieving full donor chimerism in whole blood CD3+ and leukemia-specific (CD14/15+, CD19+, CD33+ and CD34+) subset may decrease the risk of relapse of patients undergoing allogeneic transplant for hematologic malignancy.
Despite substantial progress in the treatment pediatric acute leukemia a significant number of children will experience primary or secondary resistance to the treatment. In other words it will be not possible to achieve remission using standard chemotherapy (primary resistance) or the patients will develop chemotherapy resistant relapse (secondary resistance). Children failing to achieve remission or children relapsing after previous allogeneic stem cell transplantation have short life expectancy and palliative treatment still remains the most reasonable option as the escalation of conventional chemotherapy is not longer effective. The role of Graft versus Leukemia effect was postulated as one of the mechanisms contributing to the leukemia control/eradication after transplantation of hematopoietic stem cells. In this study the investigators combine intensified multiagent Clofarabine containing chemotherapy with post-induction treatment intensification using reduced intensity conditioning followed by haploidentical hematopoietic stem cell transplantation. Introducing a new drug to the treatment of resistant leukemia the investigators want to achieve a response which allows us to proceed to immediate haploidentical transplantation. Using a haploidentical donor the investigators can avoid time consuming search for an unrelated donor and perform the transplantation at the optimal time-point. Combating therapy resistant leukemia the investigators would like to evoke and utilize potential Graft-versus-Leukemia effect which is much more pronounced in the haploidentical setting, as it is well documented that allogeneic transplantation with a matched donor is not effective in resistant disease. The use of best KIR mismatch donor and post-transplant donor lymphocyte infusion will be implemented in order to develop/intensify graft versus leukemia effect.