View clinical trials related to Neuroblastoma.
Filter by:Neuroblastoma, the most common extra-cranial solid tumour in children, remains one of the major challenges in paediatric oncology. A promising way to further improve outcome in this disease appears to be the development of adjuvant therapeutic strategies. In this research the anti-GD2 antibody, which is a standard treatment, is to be combined with 131-l Metaiodobenzylguanidine (mlBG) and anti-Programmed Cell Death Protein 1 (anti-PD1) antibody Nivolumab - the investigated drugs - with the aim of generating sustained anti-neuroblastoma immunity. In particular it will be determined the safety and tolerability of the novel combination as well as documented any evidence of efficacy in paediatric patients with relapsed and refractory high risk neuroblastoma. This study is sponsored by the University Hospital Southampton and will take place in 4 hospitals in the United Kingdom, Germany and USA. The estimated duration of the study is 2 years, starting in December 2016. This is an "adaptive study". Such design uses accumulating of data from the ongoing trial to modify aspects of the study (e.g. duration, number of treatments) without undermining its validity or integrity. There will be 3 cohorts of patients. As safety of Nivolumab is well established, Cohort 1 will assess its safety and tolerability in combination with 131-l mlBG. Cohort 2 will then add anti-GD2 to the drug combination, assessing safety and tolerability. Cohort 3 will escalate all 3 agents to the full 100% dose level to assure safety for expanded analyses of clinical and laboratory data at that dose level. Patients will initially be recruited into Cohort 1. Patients must have completed at least 12 weeks of trial treatment without reaching a Dose Limiting Toxicity before a patient can be recruited to the next cohort. A minimum of 3 evaluable patients will be treated in cohorts 1-3. Assuming the full dose combination therapy (cohort) is tolerable, 15 evaluable patients will be treated.
This research study is evaluating a novel drug called CUDC-907 as a possible treatment for resistant (refractory) pediatric solid tumors (including neuroblastoma), lymphoma, or brain tumors.
This proposal sets forth the platform for a Precision Medicine clinical trial through the New Approaches to Neuroblastoma Therapy (NANT) consortium. The plan is to utilize NANT's established multi-institutional infrastructure and Translational Genomics Research Institute GEM sequencing platform for acquisition and gene panel sequencing of relapsed biological specimens in relapsed/refractory neuroblastoma (rNB) including those obtained from the bone, bone marrow or soft tissue. Our primary aim is to identify subgroups of rNB patients who have potentially targetable genetic (ALK, MAPK pathway, Metabolic-related genes) and/or immunologic (tumor-associated macrophage infiltration and/or programmed death ligand [PD-L1] expression) biomarkers in rNB. Additional potential novel biomarkers will also be evaluated and reported in this cohort of patients.
Neuroblastoma (NB) is characterized by its wide heterogeneity in clinical presentation and evolution. Recent retrospective studies have revealed by CGH-array that the overall genomic pattern is an important prognostic marker which might be taken into account for treatment stratification. This protocol deals with a prospective analysis of the genomic profile established by CGH-array on the tumor samples obtained at the diagnosis of all the patients with NB in France, to obtain genomic profiles and being able to determine their prognostic impact in the various protocols of treatment. The objective of this study will be a better therapeutic stratification in the future trials, studies or protocols of treatment.
Patients will be asked to participate in this study because patients have been diagnosed with high-risk neuroblastoma, a common childhood cancer which has aggressive features. If left untreated, high-risk neuroblastoma is fatal. Children with high-risk neuroblastoma often respond to current available treatments, but there is a high risk that the cancer will return. This study will test the safety of giving standard induction treatment for high-risk neuroblastoma without one of the drugs commonly used to prevent side effects. Current treatment for high-risk neuroblastoma includes anti-cancer drugs (chemotherapy), surgery, radiation therapy and high-dose chemotherapy with hematopoietic stem cell rescue. Treatment takes about one year to complete and occurs in 3 phases: induction, consolidation, and maintenance. This study is limited to the induction phase of treatment. Induction therapy includes six chemotherapy drugs given in different combinations every 3 weeks for a total of 6 courses. For the past decade, induction chemotherapy has been followed by a drug called granulocyte colony stimulating factor (G-CSF, filgrastim, peg-filgrastim, Neupogen, or Neulasta) to prevent side effects from the chemotherapy. G-CSF is routinely given to patients with high risk neuroblastoma after chemotherapy to stimulate white blood cell production and shorten the time period when the absolute neutrophil count (ANC), a type of white blood cell, is low after chemotherapy. G-CSF is known to shorten the period of low ANC by approximately 3 days. When the ANC is lowest, a patient is most at risk of getting a bacterial infection. Recent lab experiments in mice have shown that neuroblastoma tumor cells may respond to G-CSF by growing faster and metastasizing (spreading to other parts of the body). There have been no clinical trials comparing the survival of children with high risk neuroblastoma with or without G-CSF. This clinical trial is the first step towards giving induction chemotherapy with less G-CSF. The goal of this study is to determine if it is safe to give induction chemotherapy to children with neuroblastoma without giving G-CSF routinely.
The purpose of this research study is to match genomic aberrations in tumor cells at time of relapse to rationally designed combinations of molecularly targeted agents. This study will be done in two parts: Part I: Tumor will be accessed at study entry via a biopsy and subjected to deep sequencing to identify protocol-specified biomarkers for therapy assignment. Part II: If the tumor contains a genetic change defined by the study as being actionable, and other criteria are met, participants will be assigned to therapy based upon the genetic changes identified in the tumor biopsy.
The purpose of this study is to improve outcome of high risk neuroblastoma by tailoring the treatment intensity of tandem high dose chemotherapy according to the treatment response to induction chemotherapy.
Patients with refractory and/or recurrent neuroblastoma have poor prognosis despite complex multimodel therapy and therefore, novel approaches are urgently needed. The investigators are attempt to treat this disease using T cells genetically modified with a 4th generation lentiviral chimeric antigen receptor (CAR) targeting GD2 (4SCAR-GD2). The 4SCAR-GD2-modified T cells can recognize and kill neuroblastoma through the recognition of GD2, a surface protein expressed at high levels on neuroblastoma but not on normal tissues. This study will evaluate the side effects and effective doses of 4SCAR-GD2 T cells in treating refractory and/or recurrent neuroblastoma.
The purpose of this first in human study is to determine the safety and feasibility of 1RG-CART therapy in patients with relapsed or refractory neuroblastoma. 1RG-CART therapy is a novel immunotherapy under investigation in which patients have their T-cells (a type of white blood cell) collected and modified in the laboratory, before they are given back to the patient. The T-cells are modified to express a chimeric antigen receptor (CAR) which targets disialoganglioside (GD2), a marker expressed on the surface of neuroblastoma cells.
The purpose of this study is to assess the safety and tolerability profile of TB-403 (humanized monoclonal antibody against placental growth factor (PlGF)) in pediatric subjects with relapsed or refractory Medulloblastoma.