View clinical trials related to Neuroblastoma.
Filter by:The purpose of this research study is to evaluate a new investigational drug (TPI 287) for neuroblastoma and medulloblastoma. An investigational drug is one that has not yet been approved by the Food and Drug Administration. This investigational drug is called TPI 287. This study will look at the tumor's response to the study drug, TPI 287, as well as the safety and tolerability of the drug. TPI 287 was shown to be effective in stopping tumor growth and was also shown to be safe in three different animal species. TPI 287 has been tested in humans in four clinical trials, and approximately 100 subjects with various types of cancers have received the drug, including a pediatric population in our previous Phase I trial.
Risks from imaging-related radiation exposure have become a popular topic in the media. Because these tests are commonly applied to patients at a cancer center, it is important to understand what patients know, how they feel about what they know, where they get their information, and how satisfied they are with available risk-benefit communication on this topic. The purpose of this study is to understand how cancer patients perceive risks and benefits of diagnostic radiation and their satisfaction with healthcare communication on this topic.
Children, adolescents and young adults with high risk relapsed or treatment refractory neuroblastoma (rNB) represent a group of patients with dismal prognosis for whom a recommended standard salvage therapy is currently not available. The multimodal metronomic approach combining molecular targeted drugs (rapamycin and dasatinib) with conventional chemotherapy (irinotecan and temozolomide) will be investigated in a randomized fashion as new treatment strategy for patients with rNB. The intention is to assess the therapeutic benefit of molecular targeted drugs for the treatment of rNB. The combination of irinotecan and temozolomide showed activity in the treatment of several solid organ tumors, brain tumors and neuroblastoma. In one study rNB patients received a median of 5 courses of 5 days irinotecan and temozolomide every 3 to 4 weeks with a cumulative dose of 35% lower than in the RIST design. 33% had disease regression with 8% CR or PR. A phase II study in rNB also using irinotecan and temozolomide with a substantially lower intensity showed a response rate of 15%. The combination of a mTOR inhibitor with a multi-kinase inhibitor demonstrated in preclinical studies a synergistic effect on cell cycle arrest, apoptosis and sensitization for radio- and chemotherapy. It is assumed that this combination of molecular targeted drugs with a tolerable conventional chemotherapy consisting of irinotecan and temozolomide can substantially improve the outcome of this patient population. A group of 20 rNB patients treated with the RIST therapy approach in a compassionate use setting showed an overall survival of 55% at a median of 80 weeks with a tolerable adverse event profile.
Allogeneic stem cell transplantation has been explored for patients with high risk neuroblastoma. Results have been mixed, with only small series and case reports. Recent reports, however, especially with haploidentical transplantation have been more encouraging. Eradication of neuroblastoma may be mediated by both components of the innate immune system (natural killer cells) and through the adaptive immune system via T-cell cytotoxicity and the development of a humoral response to tumor specific antigens and minor histocompatibility antigens. To overcome restrictions created by unavailability of Human leukocyte antigen (HLA) matched donors, stem cell grafts from haploidentical related donors have been explored. Historically, the use of full haplotype mismatched family member donors has been limited by the development of severe graft-versus-host disease and the high rate of graft failure. Graft failure can now be overcome by increasing immunosuppression and increasing the number of transplanted stem cells. The most effective means of graft versus host disease (GVHD) prophylaxis is T cell depletion of the donor marrow. A 3-4 log depletion will reduce the risk of developing significant GVHD to less than 10%. Methods to mobilize stem cells from the bone marrow into the peripheral blood and collect these stem cells by apheresis now increase the availability of stem cells by a magnitude. Selection devices have been developed that will prepare extremely pure populations of these CD34 cells with upwards of 5 logs depletion of contaminating T cells. The CliniMACS CD34 Reagent System is a medical device designed to select CD34+ hematopoietic cells from heterogeneous hematologic cell populations. The investigators intend to provide mismatched related hematopoietic stem cell transplantation to up to 10 patients with relapsed refractory neuroblastoma. Harnessing the potential for innate and adaptive immune responses through allogeneic Hematopoietic stem cell transplantation (HSCT) may provide cure for some patients with this tumor.
This is a single-center, investigator-initiated, single-arm, pilot study of post-allogeneic transplant, adoptive immunotherapy for the treatment of patients with relapsed/refractory neuroblastoma expressing the mesenchymal tumor marker GD2. Three patients will be treated. The study will focus on the safety and efficacy of allogeneic, donor derived viral specific cytotoxic T-lymphocytes, retrovirally transduced to express a chimeric antigen receptor specific for disialoganglioside, GD2, expressed on neuroblastoma.
This study will examine the safety and efficacy of ipilimumab-an experimental cancer treatment drug used to boost immune response-in children, adolescents, and young adults. Ipilimumab may allow immune cells to react to and destroy abnormal cells in the body, and has been tested in adults for a variety of cancers and has shown responses in some research studies. Because ipilimumab has not been tested in children, adolescents, or young adults, it is considered an experimental drug. The purposes of this research study are to determine the highest safe dose of ipilimumab for children, adolescents, and young adults with solid tumor cancers; examine its effectiveness and possible side effects; and better understand how the body and the immune system process it over time. Candidates must be between 2 and 21 years of age and must have solid malignant tumors that have been resistant to standard therapy. Volunteers will be screened with a medical history, a clinical examination, and computerized scans such as magnetic resonance imaging (MRI). Participants must have completed their last dose of chemotherapy, radiation, chemotherapy, or antibody or investigational therapy at least four weeks prior to enrollment. During the study, participants will receive an intravenous dose of ipilimumab once every three weeks. The infusion of ipilimumab will last 90 minutes, and the participant s vital signs will be monitored while the medicine is infusing and several times in the first 24 hours after the first dose (requiring a hospital stay during that time). If the participant is able to tolerate the first dose of ipilimumab, further doses (called cycles ) may be received on an outpatient basis. Blood and urine tests will be given on a regular basis during these cycles. After four cycles, participants whose tumors do not grow and who do not have unacceptable side effects will continue to receive ipilimumab every three months to maintain the current condition, until researchers conclude the study.
High risk neuroblastoma (NB) is an aggressive, prevalent non-brain cancer derived from nerve cells of the body. It mostly affects infants, and more children die from this tumor each year than are cured. Standard therapy includes a combination of chemotherapy, surgery, bone marrow transplant, radiation and immunotherapy. NB is very sensitive to radiation, but due to it's aggressive spread pattern, radiation use is currently limited by toxicity. This study seeks to improve delivery of radiation to reduce toxicity by quantifying outcomes, and measuring differences in renal toxicity and organ motion so that radiation can be focused more effectively against tumor while sparing normal tissues and reducing side-effects.
The purpose of this study is to find out if "humanized 3F8" (Hu3F8) is safe for treating neuroblastoma and other cancers. A phase 1 study means the investigators are trying to find out what side effects happen when higher and higher doses of a drug are used. The investigators want to find out what effects, good and/or bad, Hu3F8 has on cancer. The amount of Hu3F8 that patients gets will depend on when they start treatment on this study. The investigators also want to find out more about how Hu3F8 works and how effective it is in attacking the disease. Hu3F8 is an experimental drug, which means it has not yet been approved by the FDA for the treatment of this disease.
This research trial is studying how Ch14.18 acts in the body of younger patients with high-risk neuroblastoma. Studying samples of blood from patients with cancer receiving Ch14.18 may help doctors learn more about how this drug is used by the body to develop better ways to give the drug to potentially improve its effectiveness and lessen its side effects.
RATIONALE: Studying protein expression in samples of tumor tissue from patients with cancer in the laboratory may help doctors learn more about changes that occur in DNA and identify biomarkers related to cancer. It may also help doctors find better ways to treat neuroblastoma. PURPOSE: This laboratory studying is looking at protein expression in tumor tissue samples from patients with neuroblastoma.