Active clinical trials for "Brain Neoplasms"

The main purpose of this study is to determine the distribution of 18F Fluorocholine (18F-FCH) in the brain which can help distinguishing radiation-induced scarring from tumor regrowth. In addition, the study will measure levels of 18F-FCH in the blood and (if applicable) in the brain lesion tissue that is removed as part of the planned brain surgery.

HITC001 is a single institution study to evaluate the efficacy of using a standardized protocol of surgery and radiation for patients with brain metastases in relapsed neuroblastoma.

Several modalities have been studied to prevent coughing during emergence, including extubation in a deep plane of anesthesia but have proved to be unreliable. So far, no reliable method is recommended as standard of care. The advantages of administering tramadol includes a long duration of action, rapid recovery, limited depression of respiratory function and no effect on platelet makes it a safe medication to use for neurosurgical patients after craniotomy. The primary objective of the study is to observe the effect of single dose of tramadol (1mg/kg) administered 45 minutes before extubation on hemodynamic response (measurement of B.P and H.R) during extubation.

This is an open-label, non-randomised, phase II study to evaluate the efficacy of neratinib in combination with SOC systemic therapy on CNS metastasis both as for secondary prevention (cohort 1), primary treatment (cohort 2) and for the treatment of LM disease (cohort 3) in subjects with HER2 positive metastatic BC. Subjects with metastatic HER2 positive breast cancer will be eligible for the trial and will be enrolled in one of the following cohorts: Cohort 1: Eligible subjects include HER2 positive metastatic breast cancer subjects treated with at least one line of systemic anti HER2 therapy and pre-treated with local approaches at least for the previous CNS event and currently progressive but locally treated CNS metastasis. Local therapy includes: stereotactic radiosurgery (SRS) or/and WBRT or/and surgery. The study will measure the effect of the drug combination on the time to next CNS event(s). Cohort 2: Eligible subjects include HER2 positive metastatic breast cancer subjects treated with at least one line of systemic anti HER2 therapy or progressing less than 12 months after end of adjuvant therapy with a first diagnosis of brain metastases. The study will measure the objective CNS response in each subject. Cohort 3: Eligible subjects include HER2 positive metastatic breast cancer subjects treated with at least one line of systemic anti HER2 therapy with confirmed LM defined as the presence of malignant cells in the cerebrospinal fluid (CSF) or combination of typical symptoms and MRI. The study will measure the effect of the drug combination on the time to CNS progression including LM progression. As per investigator's choice, eligible subjects in all cohort will receive neratinib in combination with capecitabine or with T-DM1 or with paclitaxel or with vinorelbine as per investigator's choice. Trastuzumab can be added as per investigator's choice to those regimens except for T-DM1. At screening and during the study treatment period (every 9 weeks), brain MRI for cohort 1 and cohort 2 or contrast-enhanced neuraxis brain and spine MRI for cohort 3 and tumour assessment by thoracic and abdomino-pelvic CT scan for all cohorts should be performed. For cohort 3 only, CSF cytological assessment should also be performed. Additionally, at screening and at each cycle during the study treatment period, subjects must fill quality of life questionnaires: EORTC core questionnaire (QLQ-C30) and brain module (QLQ-BN20).

An Open-label, Single-arm, Single-dose, Prospective, Multicenter Phase 2b Study to Establish Image Interpretation Criteria for 18F-Fluciclovine Positron Emission Tomography (PET) in Detecting Recurrent Brain Metastases After Radiation Therapy

Patients with single brain metastasis without other metastatic site have a better prognosis, and they need a better brain metastasis control. For non-resectable and non-radiosurgical brain metastasis, the gold standard treatment is whole-brain irradiation with 30 Gy in 10 fractions, but the local control is not achieved in most of the cases. This study investigate the possibility to increase radiation dose in this metastasis with exclusive hypofractionated stereotactic radiotherapy.

The investigators want to know if using the study drug dexmedetomidine will improve nerve wave readings during neurosurgery. These readings are done many times during surgery while the patient is asleep. The readings look at how nerves are working and let the operating team know if nerves are hurt during surgery. If the readings tell that nerves are not working correctly, the surgeons can help while changing the way of operating. The study drug will be used in addition to the general anesthesia that a patient is given. The nerve readings that the investigators get while using the study drug will be compared with nerve readings that the investigators get while not using the study drug. The study hypothesis is that dexmedetomidine does not change nerve readings.

Despite significant advances in the understanding of brain tumor biology and genetics as well as improvements in surgical techniques, radiotherapy administration, and chemotherapy methods, many primary brain tumors remain incurable. Most primary brain tumors are highly infiltrative neoplasms, and are therefore unlikely to be cured by local treatments such as surgery, focal radiotherapy, radiosurgery or brachytherapy. A particularly problematic aspect of the management of patients with brain tumors is the eventual development of enhancing lesions on MRI after radiation therapy. The treating physician is then left with the dilemma of what this enhancing lesion may represent (radiation necrosis versus recurrent tumor). The differential diagnosis is between recurrent tumor or radiation necrosis however the amount of each contributing to the enhancing mass on MRI is difficult if not impossible to assess. This particular problem is very common and most patients develop some degree of radiation necrosis after therapy with radiation. Differentiation of necrosis from recurrence is particularly challenging. MRI is typically unable to make this important distinction as there is simply an enhancing mass, the etiology of which could be either necrosis or recurrence. Other imaging methods such as FDG-PET have been used but this technique is also complicated in that the normal brain has FDG uptake and it is often difficult to differentiate recurrence from necrosis. [F-18]FLT may prove to be the most reliable method in making this important differentiation (necrosis versus recurrence) as normal brain and necrotic brain do not have proliferative activity and thus no [F-18]FLT uptake whereas tumor will have proliferative activity and thus [F-18]FLT uptake.

The primary objective of this study is to assess the efficacy of the radiopharmaceutical 3'-deoxy-3'-[F-18]fluorothymidine, [F-18]FLT, a tracor of cell proliferation, using Positron Emission Tomography (PET) imaging for the tumor diagnosis and prognosis in a group of 50 patients with different type of brain tumors.[F-18]FLT PET imaging will be compared to the current used imaging techniques of MRI, spectroscopy imaging, PET imaging using [11C]MET tracer, immunohistochemical analysis and clinical parameters.

RATIONALE: Diagnostic procedures, such as magnetic resonance imaging, may help doctors predict a patient's response to treatment and help plan the best treatment. PURPOSE: This clinical trial is studying magnetic resonance imaging in response to radiation therapy in patients with high grade glioma.