View clinical trials related to Brain Lymphoma.
Filter by:Polyplastic glioblastoma and metastatic brain cancer are the most common malignant brain tumors in adults. The primary diagnostic test for tumors in the brain shows magnetic resonance imaging or similar imaging findings (especially single metastatic brain cancer) that make it difficult to distinguish between these two diseases. In addition, due to the specificity of the tissue called the brain, biopsy is not easy and sometimes biopsy is difficult, so non-invasive discrimination is often important, and it is important how much prediction is made before the biopsy. To solve this problem, various advanced magnetic resonance imaging techniques have been studied, but they are all tests that need to be additionally conducted on ordinary magnetic resonance images, and there are many subjective factors, so complex data and statistical processing methods, and many cannot be easily tested. In addition, in all of these tests, accuracy is still reported at around 60%. Therefore, if contrast-enhanced FLAIR images can be obtained along with contrast-enhanced T1 images performed during conventional magnetic resonance imaging tests to help differentiate between two diseases, it will greatly help diagnose and treat brain tumor patients and facilitate clinical application.
Primary central nervous system lymphoma (PCNSL) is an uncommon disease. Conventional treatment has consisted of either whole-brain radiation therapy (WBRT) or methotrexate (MTX)-based combined modality therapy integrating chemotherapy with cranial irradiation in a sandwiched manner. No matter whether the dosage of MTX is high or conventional, combining chemotherapy with WBRT greatly improves intracranial tumor control and even survival outcomes. However, delayed treatment-related neurotoxicity and neurocognitive sequelae emerged as a significant debilitating complication in PCNSL patients, especially when effective combined chemoradiation can achieve disease control and long-term survival rates. Therefore, by delivering hyperfractionated conformal WBRT plus SIB, this prospective cohort study aims to accomplish both optimal intracranial control and minimal WBRT induced neurocognitive decline. Additionally, by administering objective multi-domain neurobehavioral/neurocognitive assessments, the change in neurocognitive functions (NCFs) before and after the course of hyperfractionated conformal WBRT will be investigated and analyzed. According to the treatment guidelines for treating newly-diagnosed PCNSL patients, combined chemoradiation in which the WBRT course is sandwiched between initial courses of MTX and the later courses of chemotherapy with Ara-C is the treatment of mainstay at our institute. Employing the technique of a conformal CT treatment planning, the WBRT course is delivered in the manner of hyperfractionation with a reduced cumulative dose of 3600 cGy in 30 fractions during 3-4 weeks, administered twice daily in 1.2 Gy - fractions with at least 6 hours between fractions. By virtue of multidisciplinary management and teamwork including neurosurgery, hematology, radiation oncology, and neuroimaging expertise, it is attempted to recruit all potentially eligible patients with newly-diagnosed PCNSL. Most importantly, a professional neuropsychologist participates in this research project to integrate neurobehavioral outcomes into the prospective study. Accordingly, a battery of neuropsychological measures is used to evaluate predetermined NCFs for the studied patients. The test battery is composed of six standardized neuropsychological tests, covering four domains sensitive to disease and treatment effects (executive function, attention, verbal memory, information processing). The primary outcome measure is the change in patients' capability of information processing indicated by the Paced Auditory Serial Addition Test-Revised (PASAT-R), from the baseline before receiving the WBRT course to the follow-up after undergoing the entire courses of combined chemoradiation. This prospective cohort study aims to thoroughly examine newly diagnosed PCNSL patients by using a standard battery of neurobehavioral/neurocognitive functions. Additionally, a better intracranial disease control is expected since the WBRT course relies on a highly conformal treatment planning integrated with the individualized arrangement of simultaneous integrated boost (SIB) to escalate the focal dose irradiating the originally involved site(s). Moreover, WBRT-related neurocognitive sequelae might be significantly less likely to occur because the WBRT course is delivered in the fashion of hyperfractionation, indicating a significantly lower dose per fraction and a reduced cumulative dose. Furthermore, it is anticipated the investigators will analyze which neurobehavioral domain would predict the treatment-related neurocognitive impacts to the largest extent in newly diagnosed PCNSL patients treated with cranial RT combined with or without MTX based chemotherapy according to the multidisciplinary treatment guidelines implemented at a single institute.