Active clinical trials for "Brain Neoplasms"

This phase I trial is studying the side effects and best dose of erlotinib when given with temozolomide in treating young patients with recurrent or refractory solid tumors. Erlotinib may stop the growth of tumor cells by blocking the enzymes necessary for their growth. Drugs used in chemotherapy, such as temozolomide, work in different ways to stop tumor cells from dividing so they stop growing or die. Giving erlotinib with temozolomide may kill more tumor cells.

RATIONALE: Radiation therapy uses high-energy x-rays to damage tumor cells. Drugs such as RSR13 may make tumor cells more sensitive to radiation therapy. PURPOSE: Randomized phase III trial to compare the effectiveness of radiation therapy to the brain with or without RSR13 in treating patients who have brain metastases.

The purpose of this study is to compare the safety and efficacy of XERECEPT® to dexamethasone (Decadron) a common treatment for symptoms of brain swelling (edema). This study is specifically aimed at patients who require chronic high doses of dexamethasone to manage symptoms.

Malignant brain tumors are responsible for a significant amount of deaths in children and adults. Even with advances in surgery, radiation therapy, and chemotherapy, many patients diagnosed with a malignant brain tumor survive only months to weeks. In an attempt to improve the prognosis for these patients, researchers have developed a new approach to brain tumor therapy. This approach makes use of DNA technology to transfer genes sensitive to therapy into the cells of the tumor. Infections with the herpes simplex virus can cause cold sores in the area of the mouth. A drug called ganciclovir (Cytovene) can kill the virus. Ganciclovir is effective because the herpes virus contains a gene (Herpes-Thymidine Kinase TK gene) that is sensitive to the drug. Researchers have been able to separate this gene from the virus. Using DNA technology, researchers hope to transfer and implant the TK gene into tumor cells making them sensitive to ganciclovir. In theory, giving patients ganciclovir will kill all tumor cells that have the TK gene incorporated into them.

Primary malignant and non-malignant brain tumors account for an estimated 21.42 cases per 100,000 for a total count of 343,175 incident tumors based on worldwide population estimates [1]. These entities result in variable but disappointing rates of survival, particularly for primary brain tumors (5-year survival rates: anaplastic astrocytoma 27%; glioblastoma multiforme 5%) [2, 3]. Metastatic brain tumors outnumber primary brain tumors (estimates as high as 10:1) as they affect approximately 25% of patients diagnosed with cancer [4-6]. In terms of brain tumor surgery, the extent of surgical resection-a factor that is greatly impacted by a Neurosurgeon's ability to visualize these tumors-is directly associated with patient outcomes and survival [7-9]. Although spinal cord tumors are lower in terms of their incidence [10], data correlating extent-of-resection to outcomes and survival have been demonstrated in patients with intramedullary tumors [11]. Using systemically delivered compounds with a high sensitivity of detection by near-infrared (NIR) fluorescence, it would be possible for us to improve surgical resection thus minimizing chances of recurrence and improving survival. Simply, if the tumor cells will "glow" during surgery, the surgeons are more likely to identify tumor margins and residual disease, and are, therefore more likely to perform a superior cancer operation. By ensuring a negative margin through NIR imagery, it would make it possible to decrease the rates of recurrence and thus improve overall survival. This concept of intraoperative molecular imaging requires two innovations: (i) a fluorescent contrast agent that can be injected systemically into the subject and that selectively accumulates in the tumor tissues, and (ii) an imaging system that can detect and quantify the contrast agent in the tumor tissues.[12, 13] Subjects undergo intraoperative imaging, receiving an injection of indocyanine green and then undergoing intraoperative imaging of the surgery site with a NIR imaging system. The imaging devices allow the operating field to be observed in real-time.

Honest, clear, and empathetic communication between pediatric oncologists (POs) and parents of children with cancer (POCCs) is imperative to facilitating therapeutic alliance and ensuring that medical management aligns with the families' goals of care. Communication is particularly important during conversations about disease reevaluation, which often necessitate parental decision-making in the context of emotional distress. POs employ a spectrum of communication styles and strategies during challenging conversations, and there is no consensus regarding linguistic or thematic metrics for high quality communication of upsetting information. In order to better understand how POs communicate difficult information to POCCs, the investigators propose a pilot study designed to accomplish the following primary aim: Primary Objective: To identify recurrent verbal and nonverbal (e.g. the use of pauses/silence) communication techniques employed by POs in the delivery of difficult prognostic information to POCCs through content analysis of audio-recorded conversations between POs and parents of children with high risk cancer at the time of disease reevaluation. The study expects to enroll up to: 80 patient participants, 80 parents, and 15 primary pediatric oncologists (total = 175). Non-primary oncologist members of the clinical care team, extended family members, or friends of the family may also participate, if they choose to do so.

The overall aim and primary outcome of this study will be a descriptive analysis of the current treatment practice of BM in Norway. Specifically, it may give answers to the following research questions: What is the true incidence of BM in Norway? How are patients with BM treated at present? Do treatments differ between hospitals? How do treatments impact quality of life of the patients? Which factors (treatment, tumor and host variables) can explain disease control, survival, symptom relief, and general functions? How can BM staging be improved?

TREATMENT is an observational study addressing the need for knowledge and adequate diagnostic biomarkers in the response assessment of patients with brain metastasis. Reliable response assessment will be highly relevant in the coming years given the introduction of next-generation cancer drugs, including immunotherapy. This project uses advanced Magnetic Resonance Imaging (MRI) and Vessel Architecture Imaging (VAI) to better understand the response to traditional stereotactic radiosurgery (SRS) and immunotherapy. Secondary objectives include: In patients with brain metastases, use advanced MRI and Vessel Architectural Imaging methods to reveal parameters of traditional, immunotherapeutic, and anti-angiogenic therapy response. In patients with brain metastases, use advanced MRI and Vessel Architectural Imaging methods to compare results with traditional biomarkers. Use existing infrastructure at Oslo University Hospital to standardize therapy monitoring. In patients with brain metastases, use advanced MRI and Vessel Architectural Imaging methods to separate real tumor progression from treatment-induced pseudoprogression or radionecrosis In patients with brain metastases, use advanced MRI and Vessel Architectural Imaging methods to assess whether anti-angiogenic drugs improve delivery of chemotherapy.

This research is being done to determine if a short course of Chloroquine (five weeks) before, during and after whole brain radiation therapy (WBRT) will improve the overall survival of subjects being treated for brain metastases.

The goal of this clinical research study is to learn if your thinking ability (cognitive function) will be better preserved by delivering whole brain radiation therapy immediately after radiosurgical treatment of 1-3 brain metastases or to carefully observe patients after radiosurgery and hold back whole brain radiation therapy until the disease comes back.