Preoperative SRS/SRT vs Postoperative SRS/SRT for Brain Metastases
Brain MetastasesThis pilot study is a randomized, open-label, 2-arm active-controlled phase II clinical trial conducted at a single study site (UAMS). Subjects will be randomized to one of the 2 treatment arms and stratified by size of index lesion and number of brain metastases. The investigators will prospectively compare preoperative (neoadjuvant) SRS/SRT to postoperative (adjuvant) SRS/SRT in patients undergoing surgical resection for brain metastases. The investigators hypothesize that neoadjuvant SRS/SRT prior to surgical resection of brain metastases will result in improved freedom from Central Nervous System (CNS) events when compared to adjuvant SRS/SRT after surgical resection.
Measuring Brain Tumor Consistency Using Magnetic Resonance Elastography
Brain NeoplasmThis clinical trial tests whether a new imaging technique called magnetic resonance elastography (MRE) is useful in determining the consistency of brain tumors and whether this could be used to guide surgical planning and choice of approach (the type of surgery that is needed) for patients with brain tumors. Comparing MRE with the typical magnetic resonance imaging (MRI) scan may help researchers assess the quality, reliability, and diagnostic utility of this scan when evaluating brain tumors.
cCeLL - Ex Vivo (Confocal Fluorescence Endomicroscopy) for Intraoperative Brain Tumor Diagnosis...
Benign Brain TumorMalignant Brain TumorThe goal of this clinical trial is to determine if cCeLL imaging is as accurate as standard biopsy practices for brain tumor surgeries. The main question[s] it aims to answer are: Is it as accurate as standard biopsy practices? Can it be performed faster than standard biopsy practices? Participants will consent to having their tumor tissue assessed by both cCeLL and standard biopsy procedures. There are no additional participation requirements beyond the tumor removal surgery.
Feasibility of 18F-Fluciclovine PET/CT to Identify Brain Metastasis
Brain MetastasesThe goal of this diagnostic intervention clinical trial is to compare 18F-Fluciclovine uptake within brain lesions over 60 minutes compared with standard of care positive histology confirmation or confirmation MRI images. The main questions it aims to answer are: What are the dynamics of 18F-Fluciclovine update within a non-treated metastatic brain lesion over 60 minutes? What are the dynamics of 18F-fluciclovine update within recently treated metastatic brain lesions? What is the potential use of 18F-Fluciclovine in delineating true local progression from radionecrosis in patients with clinical uncertainty of indeterminate MRI? Participants will undergo an 18F-fluciclovine head PET/CT scan prior to treatment for brain metastatic lesion(s). The study will characterize uptake dynamic PET images over 60 minutes. Uptake within the lesions and the benign brain parenchyma will be plotted on a time activity curve for 60 mins. Patients will undergo a second 18F-fluciclovine PET/CT to evaluate 18F-fluciclovine uptake in treated lesions over 60 minutes. This will be offered concurrently with the post-procedure standard of care (SOC) MRI to evaluate post-treatment changes. Uptake within the lesions and the benign brain parenchyma will be plotted on a 60 min time activity curve. Results will be compared to the pre-treatment baseline images. A third 18F-fluciclovine PET/CT will be offered to evaluate post radiation changes necrosis from recurrence, for up to 10 patients in our cohort who are under clinical surveillance (up to three years surveillance) and developed MRI evidence of either true progression or radionecrosis with clinical uncertainty after stereotactic radiosurgery. The initial 18F-fluciclovine PET/CT will serve as a baseline PET/CT scan. This will be compared to post procedural histological confirmation.
Feasibility And Efficacy Of An iPad-Based Cognitive Rehabilitation Program In Brain Tumor Patients...
GliomaThis pilot clinical trial studies how well an iPad-based cognitive rehabilitation program works in improving quality of life in patients with grade II-III glioma. An iPad-based cognitive rehabilitation program may help to increase patients cognitive function and quality of life, and may provide doctors with valuable information for optimizing care of patients with brain tumors.
Study of Temozolomide to Treat Newly Diagnosed Brain Metastases
Brain MetastasesThe purpose of this study is to determine if administering temozolomide after completion of stereotactic radiosurgery helps control existing brain metastases and prevents the developement of new brain metastases.
The Use of Navigated Transcranial Magnetic Stimulation (nTMS) in the Inhibition of Neurofunctional...
Brain TumorSurgeryThe purpose of this study is to investigate the efficacy of task inhibition during TMS to confirm brain region localization. This study could provide an effective pathway for neurofunctional landmark confirmation that may be useful in a number of treatment modalities and medical considerations.
Playful Sensorimotor Training in Pediatric Brain Tumor Patients
Pediatric CancerPediatric Brain Tumor2 moreChemotherapy-induced peripheral neuropathy (CIPN) is a highly prevalent and clinically relevant side-effect of cancer treatment. The severe symptoms such as loss of sensation, numbness, pain, absent reflexes or loss of balance control not only diminish children's quality of life but also affect the medical therapy. To date, there are no effective treatment options to reduce the symptoms of CIPN. Promising results have so far been achieved with specific exercise interventions. The investigators would therefore like to conduct a prospective, multicenter, two-armed trial (RCT with follow-up). Patients (N=20) will be recruited from the Hospital for Children and Adolescents, Kantonsspital Aarau. Prior to randomization, all primarily eligible patients that have received a platin derivate or vinca-alkaloid, will be screened for symptoms of CIPN. Eligible patients with a neurologically confirmed CIPN will then be randomized either into an intervention group or a control group (CG). Patients in the intervention group will perform a standardized, age-adjusted, specific playful sensorimotor training (SMT) program twice a week for 12 weeks in addition to usual care, while the control group receives treatment as usual. The CG will be given the opportunity to participate in the intervention after study completion. Data change will be assessed at 3 time points: At baseline (T0), after 12 weeks (post intervention testing, T1), and after 12 weeks of follow-up (T2). Primary endpoint is the Ped-mTNS score in order to subjectively as well as objectively assess the severity of CIPN symptoms. It contains a short questionnaire as well as more objective parameters such as light touch sensation, pin sensibility, vibration sensibility, deep tendon reflexes and muscular strength. Additionally, the CIPN symptom pattern will be assessed via nerve conduction studies, CIPN related pain, dorsiflexion and knee extension as well as postural control. Furthermore, investigators will be evaluating patients' level of physical activity, walk to run transition time, lower limb power as well as patients integration in physical education (PE) in school and sport club activities. The investigators hypothesize that patients in the intervention group will be able to reduce relevant symptoms of CIPN, improving related physical functions and enhancing children's social reintegration.
High-Intensity Interval Exercise in Young Adult Survivors of Pediatric Brain Tumors: A Pilot Feasibility...
Pediatric Brain TumorThe purpose of this study is to determine whether a 16-week virtual, home-based, high-intensity interval training (HIIT) exercise program will improve physical, cognitive, and emotional health among young adult survivors of pediatric brain tumors. The names of the study interventions involved in this study are/is: High-Intensity Interval Training (HIIT)
Intraoperative Hyperspectral Imaging for Fluorescence Guided Surgery in Low Grade Gliomas
NeurosurgeryNeuro-Oncology1 moreThe purpose of this study is to obtain images of brain tumours during surgery using a new type of surgical camera. The study will assess how the information obtained from the images during surgery matches the removed tissue. Data will also be used to develop the system's key computer-processing features. This will enable real-time information to be given to the surgeon whilst they are performing the procedure and has the potential to make neurosurgery safer and more precise.