View clinical trials related to Meningioma.
Filter by:Meningiomas are the most common primary tumors of the central nervous system in adults. High-grade forms have a high frequency of neurofibromatosis 2 (NF2) mutations and represent 25% of meningiomas, with multiple recurrences associated with morbidity and reduced survival without medical options, including immunotherapy. The meninges play a key role in neuro-immune communication through the diversity of their immune cells and the presence of meningeal lymphatic vessels (MLV). Recent data, including from our team, shows frequent infiltration of lymphocytes and myeloid cells specific to benign meningiomas. Our hypothesis is that the immune microenvironment composed of meningeal immune cells and MLVs regulates the malignant histological progression of NF2-mutated meningiomas and their immune surveillance evasion behavior This study aims to characterize the different cellular populations of the meningioma microenvironment. We will describe the exact participation of immune and vascular cell populations in the initiation and progression of meningioma, using MRI imaging and surgical biopsies of the dura mater and meningioma in patients undergoing neurosurgery for meningioma resection.
The purpose of the proposed study is to investigate the usefulness of laser speckle contrast imaging (LSCI) compared to indocyanine green angiography (ICGA). We will collect data from a wide variety of neurovascular surgical procedures to determine when the technology is the most clinically useful. The intraoperative LSCI system provides high resolution images of blood flow in real-time without tissue contact and without the need for an exogenous contrast agent. Further study is needed to gain a better understanding of the use of the technique during surgery, but initial results suggest that the ability to identify blood flow changes with immediate feedback to the surgeon could be a significant advantage during many procedures.
Investigators will discuss the different surgical techniques for removal of spheno_orbital meningiomas with proptosis.investigators also will follow up the patient to know the outcome of removal of these tumours.
In neurosurgical setting, a large sample size trials of tranexamic acid (TXA) has been limited to TBI and SAH. The evidence of TXA in brain tumor was scarce. A few case reports support the role of TXA in brain tumor patients with significant intraoperative bleeding and difficult achieving hemostasis. To prove the benefit of TXA for an attenuation of blood loss in brain tumor patients, research with a larger sample size is required. This prospective, randomized double-blind controlled study will be conducted to evaluate the effect of TXA in reducing blood loss and blood transfusion in patients with intracranial meningiomas, diameter > 5 cm in at least 2 dimensions from the latest radiographic findings.
The goal of this study is to propose the first direct comparison of Ga-68-DOTATATE PET/CT or PET/MR and Ga-68-DOTATOC PET/CT in patients with meningioma.
Postoperative adjuvant radiotherapy is a key component of comprehensive treatment of meningioma. However, for atypical meningioma after total resection, there is still a huge controversy in patients who need adjuvant radiotherapy after surgery. Many scholars have focused on this problem and carried out some small-scale retrospective studies, but they have contradictory results. Some of the studies found that postoperative adjuvant radiotherapy could not improve the prognosis of patients, but was questioned because the sample size was too small, resulting in insignificant results, while other studies found that postoperative adjuvant radiotherapy can improve progression free survival. A study based on the National Cancer Database found that postoperative adjuvant radiotherapy and gross tumor resection are associated with a good prognosis. A recent meta-analysis enrolled a total of 757 patients and found that postoperative adjuvant radiotherapy reduced the risk of tumor recurrence but did not improve survival time. Our team reviewed the meningioma data in the SEER database and conducted a study previously. The study found that postoperative adjuvant radiotherapy did not improve the overall survival of these patients. The relevant research results were recently published in Frontiers in oncology. We further reviewed and summarized the single-center data of our hospital and found that postoperative adjuvant radiotherapy could not improve the progression free survival and overall survival of patients. Besides, we also performed a meta-analysis and found that postoperative adjuvant radiotherapy had a trend to improve progression-free survival, but there was no statistical difference. Because there are many deficiencies in previous researches, and the research results are also contradictory, it is still unclear whether patients with atypical meningioma who have undergone gross total resection can benefit from postoperative adjuvant radiotherapy. Further high quality clinical trials is still needed to be conducted in order to guide the postoperative care of patients. Therefore, we intend to conduct this multicenter randomized controlled trial to determine the value of postoperative adjuvant radiotherapy in patients with atypical meningioma who underwent gross total resection.
• Give an effective treatment for CPA-petroclival meningiomas and can detect the best approach for these tumors. . Improve the outcome of these patients and decease rate of recurrence.
Neurocognitive Outcome Assesment in Patients With Peri-optic Meningiomas After Excision With Or Without Pealing Of The Outer Layer Of The Cavernous Sinus: A Randomized Controlled Single Blinded Trial.
The trial evaluates the effect of a moderately increased radiation dose in patients with atypical (grade II) and anaplastic (grade III) meningioma after incomplete or no surgery. Endpoint is recurrence-free survival after 5 years.
Patients undergoing meningeoma resection surgery will be randomly assigned to two groups. One group will receive scalp nerve blocks with 0.5% ropivacaine, whereas the other group will receive scalp nerve blocks with 0.9% saline after anesthesia induction and before skull-pin insertion. Serum levels of TNF-α、IL-6 and IL-1β will be measured and compared at before surgery, 1h, 24h and 72h after surgery, respectively. VAS score, dosage of pain-control medicine and NRS score at the first three days after surgery, ratio of intracranial infection within 30d after surgery, and total hospitalization days and medical expenditure will also be recorded and compared between the two groups.