View clinical trials related to Leukemia.
Filter by:This phase I/II clinical trial evaluates the safety and efficacy of the combined administration of midostaurin and gemtuzumab ozogamicin in the frame of first-line standard chemotherapy in newly diagnosed acute myeloid leukemia (AML) patients displaying a cytogenetic aberration or fusion transcript in the core-binding factor (CBF) genes or FMS-like tyrosine Kinase 3 (FLT3) mutation.
The proposed study, may significantly contribute to improve healthcare delivery in patients with Chronic Myeloid Leukemia (CML) treated with modern tyrosine kinase inhibitors (TKIs) in two ways. First, it may provide novel empirical data on the positive effects of systematically monitoring of patient-reported adverse events (AEs) in routine practice for improving symptom management and adherence to therapy. Second, it will inform the development of a large international randomized controlled trial (RCT) to test whether systematic collection of patient-reported AEs, could improve clinical response to TKI therapy.
The purpose of this study is to describe the differences in quality of life (QOL) among newly diagnosed patients diagnosed with acute myeloid leukemia (AML) to help design a patient decision-making QOL model for aligning patients' choice of treatment with what matters the most to them.
Philadelphia chromosome (BCR-ABL1, Ph) is the most common genetic abnormality in acute lymphoblastic leukemia (ALL) and an independent prognostic risk factor. With the increase of age, the incidence of patients over 60 years old can reach 50%, whose 5-year overall survival rate was less than 20%. With the application of tyrosine kinase inhibitor (TKI), the prognosis of Ph positive ALL patients is greatly improved. At present, TKI combined with chemotherapy has become the first-line treatment recommended in the guideline of Ph positive ALL patients. However, with the use of imatinib, more and more patients develop drug resistant to imatinib. In addition, the clinical data showed that the MRD negative rate in patients treated with imatinib combined with hyper CVAD was only 22% three months later, which was far lower than 31% of the second generation TKI and 52% of the third generation TKI. Second generation TKI dasatinib and nilotinib can overcome most imatinib resistant kinase region mutations. However, patients with severe hemocytopenia, infection or other complications are often unable to tolerate the standard chemotherapy. In addition, due to the high cost, some patients can't afford the long-term use. Flumatinib is the first approved second generation TKI in China and a derivative of imatinib. Compared with imatinib, it introduced trifluoromethyl, substituted pyridine ring for benzene ring, and kept the direction of amide bond, which made the inhibitory effect of flumatinib on common kinase mutations significantly better than that of imatinib. In addition, compared with the second-generation TKI recommended in the first line of current guidelines, the incidence of quality of life related adverse reactions of flumatinib is lower, and no specific adverse reactions of the second-generation TKI have been reported. We plan to enroll 28 patients with Ph positive ALL. All patients are diagnosed by morphology, immunology, cytogenetics and molecular biology (MICM). According to subjects' age, we will divide them into two groups. Subjects aged 60 years or older are received flumatinib and dose-adjusted VDCP or prednisone regimen. Subjects younger than 60 years are received flumatinib and hyper-CVAD regimen. MRD are examined on the 8th, 15th and 29th day after chemotherapy. Then, MRD will be monitored in the third, 6th, 9th, 12th, 15th, 18th, 21th and 24th months after chemotherapy to evaluate the effect.
This phase I trial studies the best dose of total body irradiation when given with cladribine, cytarabine, filgrastim, and mitoxantrone (CLAG-M) or idarubicin, fludarabine, cytarabine and filgrastim (FLAG-Ida) chemotherapy reduced-intensity conditioning regimen before stem cell transplant in treating patients with acute myeloid leukemia, myelodysplastic syndrome, or chronic myelomonocytic leukemia that has come back (relapsed) or does not respond to treatment (refractory). Giving chemotherapy and total body irradiation before a donor peripheral blood stem cell transplant helps kill cancer cells in the body and helps make room in the patient's bone marrow for new blood-forming cells (stem cells) to grow. When the healthy stem cells from a donor are infused into a patient, they may help the patient's bone marrow make more healthy cells and platelets and may help destroy any remaining cancer cells. Sometimes the transplanted cells from a donor can attack the body's normal cells called graft versus host disease. Giving cyclophosphamide, cyclosporine, and mycophenolate mofetil after the transplant may stop this from happening.
A prospective, single-arm, multicenter, exploratory study to evaluate the efficacy and safety of D-CLAG regimen in the treatment of relapsed or refractory acute myeloid leukemia
This study will validate a previously developed pediatric prognostic biomarker algorithm aimed at improving prediction of risk for the later development of chronic graft-versus-host disease (cGvHD) in children and young adults undergoing allogeneic hematopoietic stem cell transplant. By developing an early risk stratification of patients into low-, intermediate-, and high-risk for future cGvHD development (based upon their biomarker profile, before the onset of cGvHD), pre-emptive therapies aimed at preventing the onset of cGvHD can be developed based upon an individual's biological risk profile. This study will also continue research into diagnostic biomarkers of cGvHD, and begin work into biomarker models that predict clinical response to cGvHD therapies.
Among the most notable cancer genome-wide sequencing discoveries in recent years was the finding of mutation hot-spots in the isocitrate dehydrogenase (IDH) genes in grade II/III astrocytomas and oligodendrogliomas and in secondary glioblastomas. This was rapidly followed by identification of recurrent IDH1/2 mutations in myeloid neoplasms (MN), including acute myeloid leukemia (AML). Mutant IDH is now a therapeutic target of great interest in cancer research, especially in AML, given the limitations of current approved therapies and the encouraging early clinical data demonstrating proof of concept for investigational mutant IDH1/2 inhibitors. The origin of mutations in AML was explored by investigating the clonal evolution of genomes sequenced from patients with M1- or M3-AML and comparing them with hematopoietic stem/progenitor cells (HSPCs) from healthy volunteers. Six genes were found to have statistically higher mutation frequencies in M1 versus M3 genomes (NPM1, DNMT3A, IDH1, IDH2, TET2 and ASXL1), suggesting they are initiating rather than cooperating events. Prospective evaluation of serial 2- HG levels during treatment of newly diagnosed AML treated with standard chemotherapy revealed that both 2-HG level and mutated IDH allele burden decreased with response to treatment but began to rise again as therapy failed. The prognostic impact of IDH mutations in AML is under continued investigation and varies across studies. In this research project authors aim a) to define the prevalence and type of IDH1/2 mutations in AML patients; b) to define relationships between IDH1/2 mutations and other oncogenic mutations in AML, as well as to describe clonal evolution of the disease and c) to describe the clinical outcome of IDH1/2 mutated patients with AML treated with currently available treatments.
Haematological malignancies constitute the most common neoplastic disease in child population, with acute leukemia occupying the number one spot with a percentage of 32.8%. In children, leukaemia is primarily encountered in its acute form (97%) and in the majority of the cases it is presented as Acute Lymphoblastic Leukaemia - ALL (80%). Acute Non-Lymphoblastic Leukemia - ANLL is encountered less frequently (17%) and it includes Acute Myelogenous Leukaemia - AML (15%) and some other rare forms (2%), while the remainder 3% corresponds to chronic leukaemia. L-Asparaginase (L-ASP) is a fundamental component during the loading phase with regards to achieving remission of the disease and, likewise, during the maintenance phase with the intention of establishing that remission in both children and adults suffering from ALL. The cytotoxic effect of the exogenous administration of Asparaginase is caused by the depletion of the reserve of asparagine in the blood. Asparaginase (ASP) acts as a catalyst for the hydrolysis of asparagine to aspartic acid and ammonia. Asparagine is vital for protein and cell synthesis and, therefore, for their survival. The normal cells of the human body have the ability to produce asparagine from aspartic acid, with the assistance of the enzyme asparagine synthetase. However, the neoplastic cells either lack the enzyme completely or contain minute amounts of it resulting in their inability to synthesize asparagine de novo. The survival of these cells and their ability to synthesize proteins depends entirely on receiving asparagine from the blood. Thus, the administration of ASP leads to the inhibition of DNA, RNA and protein synthesis which, in turn, results in the apoptosis of these cells. Despite L-ASP's paramount importance in the chemotherapy treatment of leukaemia, it is responsible for a plethora of toxic adverse effects that sometimes even require the termination of its administration. A critical adverse event of ASP is a disorder in the metabolism of lipids. Specifically, it appears that the activation of the endogenous pathway that produces triglycerides through hepatic synthesis leads to hypertriglyceridaemia. The liver is capable of synthesizing VLDL (Very Low Density Lipoproteins) that are rich in triglycerides. Utilising the effect of the enzyme Lipoprotein Lipase (LpL), located on the vascular endothelium, the triglycerides detach from the VLDL causing the latter to transform into IDL (Intermediate Density Lipoproteins) and afterwards into LDL (Low Density Lipoproteins). The triglycerides are later extracted from the blood circulatory system and stored in the adipose tissue, while the LDL particles connect with tissue receptors or macrophage receptors. The final products of the breakdown (coming from the peripheral hydrolysis of triglycerides with the help of LpL) of chylomicrons, VLDL, the remnants of lipoproteins, will eventually be removed by hepatic receptors. Apolipoprotein E (Apo-E) plays an important role in this procedure, it binds these remnants in the presence of LpL and hepatic lipase. Along the duration of the treatment with ASP, reduced LpL functionality is recorded, resulting in impaired plasma clearance of triglycerides and an increase in their levels, while L-ASP appears to cause disorders in other lipid factors, such as cholesterol, HDL and apolipoprotein A. Disorders of lipid metabolism have been found to be associated with polymorphisms of the LpL and Apo-E genes, sometimes with positive and sometimes with negative effects on the lipid profile and more likely participation in cardiovascular complications. The current study will evaluate, the lipid profile of children with ALL, the effect of L-ASP on the lipid profile of the aforementioned patients, as well as the correlation between the polymorphisms of Lipoprotein Lipase (LpL) and Apolipoprotein E (ApoE) with the values of the lipids during chemotherapy. Both the universal and national bibliography that pertain to the effect of ASP on the potency of LpL and App E and to the values of the lipids in children that suffer from ALL during chemotherapy with L-ASP is limited, while there exists no bibliographic reference correlating the genetic background to LpL and Apo E and the relation of the lipid profile. The current study will examine for the first time gene polymorphisms of LpL and Apo E in children with ALL during treatment with ASP.
There are no strategies developed post-stem cell transplant (SCT) for patients who receive allogenic SCT with a significant amount of blasts prior SCT. Novel strategies to treat relapsed AML/MDS and to reduce the incidence of relapse after allogeneic SCT are needed. This study is being done in patients with high-risk MDS or AML who undergo an allogeneic SCT. The study will have two arms, participants who receive an HLA-matched unrelated donor SCT (Arm A) or HLA- haploidentical SCT (Arm B). Following myeloablative conditioning (MAC), GVHD prophylaxis with post-transplantation cyclophosphamide (PTCy), tacrolimus and mycophenolate mofetil will be given per standard of care. At 40-60 days post SCT, If the patient has not had any evidence of Grade II-IV acute graft-versus-host-disease (aGVHD), Nivolumab will be given intravenously every 2 weeks for 4 cycles of consolidation or treatment with Nivolumab. Dose-escalation of Nivolumab will follow the standard 3+3 design where a maximum of three dose levels will be evaluated, with a maximum of 18 patients treated with nivolumab per arm. As the maximum tolerated dose (MTD) of Nivolumab may differ between Arm A and Arm B, dose escalation of nivolumab in each arm will be followed separately following allogeneic SCT. Immunosuppression with tacrolimus will be continued during the cycles of PD-1 blockade to provide a moderate level of GVHD prophylaxis during consolidation or treatment with nivolumab.