Active clinical trials for "Neuroblastoma"

This phase III trial studies iobenguane I-131 or lorlatinib and standard therapy in treating younger patients with newly-diagnosed high-risk neuroblastoma or ganglioneuroblastoma. Radioactive drugs, such as iobenguane I-131, may carry radiation directly to tumor cells and not harm normal cells. Lorlatinib may stop the growth of tumor cells by blocking some of the enzymes needed for cell growth. Giving iobenguane I-131 or lorlatinib and standard therapy may work better compared to lorlatinib and standard therapy alone in treating younger patients with neuroblastoma or ganglioneuroblastoma.

The study evaluates CLR 131 in children, adolescents, and young adults with relapsed or refractory malignant solid tumors and lymphoma and recurrent or refractory malignant brain tumors for which there are no standard treatment options with curative potential.

Neuroblastoma is the most common extracranial solid tumor in childhood, with nearly 50% of patients presenting with widespread metastatic disease. The current treatment for this group of high-risk patients includes intensive multi-agent chemotherapy (induction) followed by myeloablative therapy with stem-cell rescue (consolidation) and then treatment of minimal residual disease (MRD) with isotretinoin. Recently a new standard of care was established by enhancing the treatment of MRD with the addition of a monoclonal antibody (ch14.18) which targets a tumor-associated antigen, the disialoganglioside GD2, which is uniformly expressed by neuroblasts. Despite improvement in 2-year event-free survival (EFS) of 20%, more than one-third of children with high-risk neuroblastoma (HR defined in) still cannot be cured by this approach. Therefore, novel therapeutic approaches are needed for this subset of patients. This study will be a pilot Phase II study of a unique anti-disialoganglioside (anti-GD2) monoclonal antibody (mAb) called hu14.18K322A, given with induction chemotherapy. PRIMARY OBJECTIVE: To study the efficacy [response: complete remission + partial remission (CR+PR)] to two initial courses of cyclophosphamide and topotecan combined with hu14.18K322A (4 doses/course followed by GM-CSF) in previously untreated children with high-risk neuroblastoma. To estimate the event-free survival of patients with newly diagnosed high-risk neuroblastoma treated with the addition of hu14.18K322A to treatment. SECONDARY OBJECTIVES: To study the feasibility of delivering hu14.18K322A to 6 cycles induction chemotherapy and describe the antitumor activity (CR+PR) of this 6 course induction therapy. To estimate local control and pattern of failure associated with focal intensity modulated or proton beam radiation therapy dose delivery in high-risk abdominal neuroblastoma. To describe the tolerability of four doses of hu14.18K322A with allogeneic natural killer (NK) cells from an acceptable parent, in the immediate post-transplant period [day +2 - +5 after peripheral blood stem cell (PBSC) infusion] in consenting participants. To describe the tolerability of hu14.18K322A with interleukin-2 and GM-CSF as treatment for minimal residual disease (MRD).

Subjects that have relapsed or refractory neuroblastoma are invited to take part in this gene transfer research study. We have found from previous research that we can put a new gene called a chimeric antigen receptor (CAR) into T cells that will make them recognize neuroblastoma cells and kill them. In a previous clinical trial, we used a CAR that recognizes GD2, a protein found on almost all neuroblastoma cells (GD2-CAR). We put this gene into T cells and gave them back to patients that had neuroblastoma. The infusions were safe and in patients with disease at the time of their infusion, the time to progression was longer if we could find GD2 T cells in their blood for more than 6 weeks. Because of this, we think that if T cells are able to last longer, they may have a better chance of killing neuroblastoma tumor cells. Therefore, in this study we will add new genes to the GD2 T cells that can cause the cells to live longer. These new genes are called CD28 and OX40. The purpose of this study will be to determine the highest dose of iC9-GD2-CD28-OX40 (iC9-GD2) T cells that can safely be given to patients with relapsed/refractory neuroblastoma. In other clinical studies using T cells, some investigators found that giving chemotherapy before the T cell infusion can improve the amount of time the T cells stay in the body and therefore the effect the T cells can have. This is called lymphodepletion and we think that it will allow the T cells we infuse to expand and stay longer in the body, and potentially kill cancer cells more effectively. The chemotherapy we will use for lymphodepletion is a combination of cyclophosphamide and fludarabine. Additionally, to effectively kill the tumor cells, it is important that the T cells are able to survive and expand in the tumor. Recent studies have shown that solid tumors release a substance (PD1) that can inhibit T cells after they arrive into the tumor tissue. In an attempt to overcome the effect of PD1 in neuroblastoma we will also give a medication called pembrolizumab.

Neuroblastoma is the second most common solid tumor seen in children, but causes approximately 15% of childhood cancer deaths each year. Patients with high-risk disease require treatment with a combination of chemotherapy, surgery, radiation, and stem cell transplant; however, many will have their disease come back within 3 years. Due to this high rate of relapse, this study is being done to investigate an experimental treatment option for children whose disease has returned. This clinical trial is for patients with neuroblastoma that has either come back after treatment or never went away in the first place. A series of immunizations will be administered using a tumor vaccine and add low-dose chemotherapy to be taken by mouth on a daily basis. The hope is that the vaccine will cause the immune system to recognize and kill more types of neuroblastoma tumors. Additionally, the immunizations will be combined with daily low dose chemotherapy. Daily low-dose chemotherapy, also know as metronomic chemotherapy, works by attacking the blood vessels that allow tumors to grow. Using metronomic doses of a drug called cytoxan can also decrease T regulatory cells, a specific type of cell that tumors use to hide from the immune system. The purpose of this study is to test the safety and anti-tumor effect of the tumor cell vaccination plus low dose, metronomic chemotherapy in treating patients with relapsed/refractory neuroblastoma.

Patients have high-risk neuroblastoma, a form of cancer typically found in children. The patients previously participated in a gene transfer research study using special immune cells. This research study combines two different ways of fighting disease, antibodies and T cells. Antibodies are types of proteins that protect the body from bacterial and other infections. T cells, also called cytotoxic T lymphocytes or CTLs, are special infection-fighting blood cells that can kill some tumor cells. Both antibodies and T cells have been used to treat patients with cancers and while they have shown promise, they have not been strong enough to cure most patients. The antibody used in this study is called 14g2a. This antibody sticks to neuroblastoma cells because of a substance on the outside of these cells called GD2. 14g2a and other antibodies that bind to GD2 have been used to treat people with neuroblastoma. For this study 14g2a has been changed so that instead of floating free in the blood, it is now joined to T cells. When an antibody is joined to a T cell in this way it is called a chimeric receptor. T lymphocytes or CTLs can kill tumor cells but there normally are not enough of them to kill all tumor cells. Some researchers have taken T cells from a person's blood, grown more of them in the laboratory and then given them back to the patient. Sometimes an antibody or chimeric receptor is attached to these T cells to help them bind to tumor cells. These chimeric receptor-T cells seem to kill some of the tumor, but they don't last very long in the body and so the tumor eventually comes back. We have found that T cells that are also trained to recognize the virus that causes infectious mononucleosis, Epstein Barr Virus (EBV), can stay in the blood stream for many years. By joining the 14g2a antibody to the CTLs that recognize EBV, we believe we will make a cell that can last a long time in the body (because they are EBV-specific) and recognize and kill neuroblastoma cells (because an antibody that can recognize these cells has been placed on their surface). Patients received treatment with the immune cells described above. They may want to receive an additional dose of these cells. This is being offered as an option because their neuroblastoma has returned and they have enough cells remaining to provide the patients with an additional dose. These 14g2a antibody CTLs are an investigational product not approved by the Food and Drug Administration.

131I-Metaiodobenzylguanidine (131I-MIBG) is one of the most effective therapies utilized for neuroblastoma patients with refractory or relapsed disease. In this pediatric phase 1 trial, 131I-MIBG will be given in combination with dinutuximab, a chimeric 14.18 monoclonal antibody. This study will utilize a traditional Phase I rolling 6 dose escalation design to determine a recommended phase 2 pediatric dose. An expansion cohort of an additional 6 patients will then be enrolled. If tolerable, vorinostat will then be added to the third dose level. A 6 patient expansion cohort may then be enrolled.

This phase II Pediatric MATCH trial studies how well palbociclib works in treating patients with Rb positive solid tumors, non-Hodgkin lymphoma, or histiocytic disorders with activating alterations (mutations) in cell cycle genes that have spread to other places in the body and have come back or do not respond to treatment. Palbociclib may stop the growth of cancer cells by blocking some of the proteins needed for cell growth.

The purpose of this study is to test see the combined effects of the study drug called Humanized 3F8 (Hu3F8) when used with granulocyte-macrophage colony stimulating factor (GM-CSF). Hu3F8 plus GM-CSF could prevent your neuroblastoma from growing, but it could also cause side effects.

This phase II Pediatric MATCH trial studies how well selumetinib sulfate works in treating patients with solid tumors, non-Hodgkin lymphoma, or histiocytic disorders with MAPK pathway activation mutations that have spread to other places in the body and have come back or do not respond to treatment. Selumetinib sulfate may stop the growth of cancer cells by blocking some of the enzymes needed for cell growth.