View clinical trials related to Diffuse Intrinsic Pontine Glioma.
Filter by:The blood brain barrier (BBB) prevents some drugs from successfully reaching the target tumor. Focused Ultrasound (FUS) using microbubbles and neuro-navigator-controlled sonication is a non-invasive method of temporarily opening up the blood brain barrier to allow a greater concentration of the drug to reach into the brain tumor. This may improve response and may also reduce system side effects in the patient. The primary purpose of this study is to evaluate the feasibility of safely opening the BBB in children with progressive diffuse midline gliomas (DMG) treated with oral Panobinostat using FUS with microbubbles and neuro-navigator-controlled sonication. For the purpose of the study, the investigators will be opening up the BBB temporarily in one, two, or three locations around the tumor using the non-invasive FUS technology, and administrating oral Panobinostat in children with progressive DMG.
This study will evaluate the safety of BXQ-350 and determine the maximum tolerated dose (MTD) in children with newly diagnosed DIPG or DMG. All patients will receive BXQ-350 by intravenous (IV) infusion and radiation therapy. The study is divided into two parts: Part 1 will enroll patients at increasing dose levels of BXQ-350 in order to determine the MTD. Part 2 will enroll patients requiring a biopsy in order to assess BXQ-350 concentrations in the biopsied tumor.
The aim of this study is to assess the safety and efficacy of AloCELYVIR, which consist in bone marrow-derived allogenic mesenchymal stem cells infected with an oncolytic Adenovirus, ICOVIR-5. It has recently been proven that this type of cells are able of transporting oncolytic substances to tumor targets that are difficult to reach, such as medulloblastomas and gliomas, youth cancers located in the cranial cavity that have a poor prognosis and a fatal outcome. In addition, to exerting an anti-tumor action, this virus has the ability to stimulate the immune response, making the therapy even more effective. Thus, the diffuse intrinsic pontine glioma and the medulloblastoma in relapse/progression have been chosen to study the potential of this new advanced therapy through a weekly infusion for 8 weeks.
Diffuse intrinsic pontine gliomas (DIPGs), which diffusely occupy the pons of brainstem, are the deadliest primary brain cancer in children. Biopsy for pathology plus radiotherapy remains the current standard-of-care treatment that is minimal effective. Thus, the median overall survival after diagnosis is just 10 months. Recent studies have identified a lysine 27-to-methionine (K27M) somatic mutation at histone H3 variant (H3.3), as a feature mutation in DIPGs. Several preclinical studies have already demonstrated H3.3-K27M as a promising target for immunotherapy. The researched vaccine is a cancer-treatment vaccine containing an H3.3-K27M targeted neoantigen peptide, that can be taken up by antigen-presenting cells (APCs). APCs can present the peptide with the major histocompatibility complex (MHC) molecules on cell surface, thereby activating neoantigen-specific T cells and triggering corresponding cytotoxic T cell immune responses to eliminate H3.3-K27M-expressing DIPG cells. The main goal of this study is investigating the safety and preliminary efficacy of the vaccine in treating newly-diagnosed DIPGs when the vaccine is administered in combination with the standard-of-care treatment.
Although many children with brain tumours are successfully cured of their disease, a substantial proportion of patients suffer disease recurrence and require further treatment. This therapy may involve a repeat course of radiation (RT2). Based on retrospective data, re-irradiation may provide palliative and even potentially curative benefit. However, such retrospective data are subject to bias, which may over-report survival and under-report toxicity. Furthermore, we do not know how re-irradiation affects patients' HRQOL. The goal of this research is to prospectively describe the HRQOL of patients diagnosed with DIPG and recurrent brain tumors and their families before and after re-irradiation to more accurately assess the benefit versus the toxicity of this treatment. In addition, if we are able to demonstrate the feasibility of collecting HRQOL information on a routine basis we will be able to justify the need to conduct this research further and implement HRQOL screening as a standard of care for these patients. Re-irradiation for children with DIPG and recurrent brain tumours will not cure these children from their disease but may improve neurological function and wellbeing. We postulate that the opportunity of more time to say the final good bye and creating memories will facilitate bereavement and prevent psychological dysfunction of parents and siblings. A greater understanding of what helps these families may enable clinicians to better support these children and their families in this difficult disease course. Ultimately our goal is to improve the psychological experience of these patients and their families.
This is a pilot study that will evaluate disease status in children that have been newly diagnosed high-grade glioma with TRK fusion. The evaluation will occur after 2 cycles of the medication (Larotrectinib) have been given. The study will also evaluate the safety of larotrectinib when given with chemotherapy in your children; as well as the safety larotrectinib when given post-focal radiation therapy.
This is a prospective, open-label, single arm, multicenter clinical study. The purpose of the study is to evaluate the clinical efficacy and safety of combination Nimotuzumab with concurrent radiochemotherapy in children with newly diagnosed diffuse intrinsic pontine glioma(DIPG).
This research study is evaluating the safety, tolerability and preliminary efficacy of the drugs marizomib and panobinostat in pediatric patients with diffuse intrinsic pontine glioma (DIPG). The names of the study drugs involved in this study are: - Marizomib - Panobinostat
The blood brain barrier (BBB) prevents some drugs from successfully reaching the target source. Convection-Enhanced Delivery (CED) is a method of direct infusion of drugs under controlled pressure to the tumor that may reduce systemic side effects of drugs in the patient. The purpose of this Phase I study is to find the maximum tolerated dose of MTX110 (a water-soluble Panobinostat nanoparticle formulation) and Gadolinium that can be given safely in children with newly diagnosed diffuse midline gliomas. All patients enrolled in the study will receive infusion of MTX110 and Gadolinium delivered with a pump directly into the tumor over 9-11 days.
In this study, the investigators are testing improvement in survival outcomes in DIPG patients when stratified with MR perfusion score and treated with the said protocol. Newly diagnosed DIPG patients will undergo MRI perfusion study in addition to the usual MRI at diagnosis and will be stratified into hyperperfused or hypoperfused tumours. The hyperperfused patients will receive additional low dose Bevacizumab weekly with conventional standard radiotherapy. The hypo-perfused patients will receive ultra-low-dose radiotherapy fractionation equivalent to conventional RT biological dose.