View clinical trials related to Neuroblastoma.
Filter by:Children and adults diagnosed with high-risk neuroblastoma patients with primary refractory disease or incomplete response to salvage treatment in bone and/or bone marrow will be treated for up to 101 weeks with naxitamab and granulocyte-macrophage colony stimulating factor (GM-CSF). Patients will be followed for up to five years after first dose. Naxitamab, also known as hu3F8 is a humanised monoclonal antibody targeting GD2
This research study combines two different ways of fighting cancer: antibodies and Natural Killer T cells (NKT). Antibodies are types of proteins that protect the body from infectious diseases and possibly cancer. T cells, also called T lymphocytes, are special white blood cells that can kill other cells, including cells infected with viruses and tumor cells. Both antibodies and T cells have been used to treat patients with cancers. Investigators have found from previous research that they can put a new gene into T cells that will make them recognize cancer cells and kill them. In a previous clinical trial, investigators made artificial genes called a chimeric antigen receptors (CAR), from an antibody called 14g2a that recognizes GD2, a molecule found on almost all neuroblastoma cells (GD2-CAR). Investigators put these genes into the patients' own T cells and gave them back to patients that had neuroblastoma. NKT cells are another special subgroup of white blood cells that can specifically go into tumor tissue of neuroblastoma. Inside the tumor, there are other white blood cells called macrophages which help the cancer cells to grow and recover from injury. NKT cells can specifically kill these macrophages and slow the tumor growth. We will expand NKT cells and add GD2-specific chimeric antigen receptors to the cells. We think these cells might be better able to attack NB since they also work by destroying the macrophages that allows the tumor to grow. The chimeric antigen receptor will also contain a gene segment to make the NKT cells last longer. This gene segment is called CD28. In addition, to further improve the antitumor activity of the GINAKIT cells we added another gene expressing a molecule called Interleukin -15 (IL-15). The combination of these 3 components showed the most antitumor activity by CAR expressing NKT cells and improved these cells' survival in animal models. GD2-CAR expressing NKTs have not been tested in patients so far. The purpose of this study is to find the largest effective and safe dose of GD2-CAR NKT cells (GINAKIT cells), to evaluate their effect on the tumor and how long they can be detected in the patient's blood and what affect they have on the patient's neuroblastoma.
Neuroblastoma is a neoplasm of the sympathetic nervous system which affects mostly children younger than 5 years of age. It is a heterogeneous disease, with nearly 50% of patients presenting with a high-risk phenotype. After standard treatment, the 2-year event-free survival (EFS) for high risk neuroblastoma (EFS) is only about 50%. Immunotherapy with anti-GD2 antibodies has been shown to improve EFS in Children's Oncology Group and SIOPEN trials. The anti-GD2 antibody mediates neuroblastoma cell killing primarily through antibody-dependent cell-mediated cytotoxicity (ADCC). Natural killer (NK) cells are the main effectors of ADCC. We postulate that infusion of expanded activated NK cells from healthy haploidentical donors along with anti-GD2 antibody will enhance neuroblastoma killing.
This phase II Pediatric MATCH trial studies how well ensartinib works in treating patients with solid tumors, non-Hodgkin lymphoma, or histiocytic disorders with ALK or ROS1 genomic alterations that have come back (recurrent) or does not respond to treatment (refractory) and may have spread from where it first started to nearby tissue, lymph nodes, or distant parts of the body (advanced). Ensartinib may stop the growth of tumor cells by blocking some of the enzymes needed for cell growth.
This Pediatric MATCH screening and multi-sub-study phase II trial studies how well treatment that is directed by genetic testing works in pediatric patients with solid tumors, non-Hodgkin lymphomas, or histiocytic disorders that have progressed following at least one line of standard systemic therapy and/or for which no standard treatment exists that has been shown to prolong survival. Genetic tests look at the unique genetic material (genes) of patients' tumor cells. Patients with genetic changes or abnormalities (mutations) may benefit more from treatment which targets their tumor's particular genetic mutation, and may help doctors plan better treatment for patients with solid tumors or non-Hodgkin lymphomas.
NOTE: This is a research study and is not meant to be a substitute for clinical genetic testing. Families may never receive results from the study or may receive results many years from the time they enroll. If you are interested in clinical testing please consider seeing a local genetic counselor or other genetics professional. If you have already had clinical genetic testing and meet eligibility criteria for this study as shown in the Eligibility Section, you may enroll regardless of the results of your clinical genetic testing. While it is well recognized that hereditary factors contribute to the development of a subset of human cancers, the cause for many cancers remains unknown. The application of next generation sequencing (NGS) technologies has expanded knowledge in the field of hereditary cancer predisposition. Currently, more than 100 cancer predisposing genes have been identified, and it is now estimated that approximately 10% of all cancer patients have an underlying genetic predisposition. The purpose of this protocol is to identify novel cancer predisposing genes and/or genetic variants. For this study, the investigators will establish a Data Registry linked to a Repository of biological samples. Health information, blood samples and occasionally leftover tumor samples will be collected from individuals with familial cancer. The investigators will use NGS approaches to find changes in genes that may be important in the development of familial cancer. The information gained from this study may provide new and better ways to diagnose and care for people with hereditary cancer. PRIMARY OBJECTIVE: - Establish a registry of families with clustering of cancer in which clinical data are linked to a repository of cryopreserved blood cells, germline DNA, and tumor tissues from the proband and other family members. SECONDARY OBJECTIVE: - Identify novel cancer predisposing genes and/or genetic variants in families with clustering of cancer for which the underlying genetic basis is unknown.
The purpose of this study is to explore the effect of G-CSF combination with GM-CSF on prevention and treatment of infection in children with malignant tumor.
This single-arm, multicenter clinical study will treat the patient who have relapsed or refractory neuroblastoma with an infusion of the patient's own T cells that have been genetically modified to express a chimeric antigen receptor(CAR)that will bind to tumour cells modified to express the GD2 protein on the cell surface. The study will determine if these modified T cells help the body's immune system eliminate tumour cells .The trial will also study the safety of treatment for CAR-T, how long CAR-T cells stay in the patient's body and the impact on this treatment for survival.
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.
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.