View clinical trials related to Glioblastoma.
Filter by:Glioblastoma (GBM) is the most common primary brain cancer in adults. Surgery, chemoradiotherapy (temozolomide TMZ) and then adjuvant TMZ is the standard treatment. But, most patients relapse in a median time of 8-9 months; the median overall survival (OS) ranged from 15 to 18 months. Some frail patients received hypofractionated radiation and concomitant and adjuvant TMZ. For some, the radiation dose is not optimal. Moreover, recurrences develop mainly in the initial tumor site. These two reasons justify increasing the dose. To limit the movements of these fragile patients, the method consists of increasing the dose without increasing the number of sessions by using the Simultaneous Integrated Boost (SIB) which increases the dose in targeted volumes while the rest of the volume receives a minimum dose. A phase I trial showed the possibility of increasing the dose in SIB up to 80 Gy in a part of the GBM enhanced on MRI. FDOPA PET detects certain more aggressive tumor areas, areas likely to recur. Integrating them into the SIB seems appropriate. A phase II trial showed the interest of SIB guided by FDOPA PET in terms of progression-free survival but without impact on OS. This study differed from the one the investigators propose, because a dose and conventional fractionation, identical to that of the European Organization for Research and Treatment of Cancer/National Cancer Information Center (NCIC/EORTC) protocol were delivered, the gliomas were unmethylated MGMT, less likely to respond. Studies with SIB and hypofractionation are often retrospective and for others, hypofractionation was debatable and the dose increase was not based on PET capture but on MRI. However, a prospective phase II study, with SIB and hypofractionation, not integrating FDopa PET has demonstrated the relevance of SIB. In this project, the investigators propose to use the integrated boost technique (SIB) guided by PET FDOPA to increase the radiation dose in GBM, in patients either fragile and partially operated, or only biopsied and for whom the prognosis is the most pejorative.
This trial is set up as a prospective observational cohort study to identify if either biopsy or resection should be the surgical modality of choice in elderly glioblastoma patients with a newly diagnosed tumor. Patients who are considered eligible for GBM resection or biopsy will be included. Through shared-decision making patients and their treating physicians will decide upon resection or biopsy. Written informed consent will be obtained. Participants will be followed for 1 year postoperative to assess potential differences in health-related quality of life and overall survival. Follow-up will consist of health-related quality of life questionaires and neurological assessment at 6 weeks, 3 months, 6 months and 12 months postoperative. Additionally Cognitive and neuro-linguistic tests will be done at 3 months postoperative. These will be compared to results pre-operative. After surgery, patients will receive standard adjuvant treatment with concomitant Temozolomide and radiation therapy, and standard follow-up. Patients in whom the diagnosis GBM is not confirmed in histological analyses will be excluded from the study. Total study duration will be 4 years, of which 3 years will comprise patient inclusion, with a follow-up duration of 1 year.
The purpose of this study is to evaluate relationships between multiparametric imaging biomarkers and genetic analysis in glioblastoma patients.
The purpose of this study is to evaluate the clinical efficacy and safety of Tislelizumab (one anti-PD-1 antibody same as nivolumab approved in China) in combination with bevacizumab in patients with recurrent or progressive glioblastoma (GBM) who have progressed on bevacizumab with or without PTEN or TERT gene mutations.
Tumor in situ fluid (TISF) refers to the fluid within the surgical cavity of patients with glioblastoma. Postoperative serial TISF is collected for circulating tumor DNA (ctDNA) analysis and identifying ctDNA-level relapse driven by one or a set of specific genomic alterations before overt imaging recurrence of the tumor. This single-arm open-label prospective pilot feasibility trial recruiting 20 adult patients with ctDNA-level-relapse glioblastoma who are assigned to receive the personalized study treatment based on the genetic profile of their serial TISF ctDNA. It will be aimed to test whether the personalized intervention can prolong the progression-free and overall survival and the feasibility of conducting a full-scale trial.
It is a single-center, prospective, observational,non-randomized study of newly diagnosed glioblastoma patients conducted in a tertiary hospital. The investigators examine the psychological stress, immune biomarker changes, quality of life, and disease progression of patients with glioblastoma at five-time points. The study had two cohorts, a high-stress cohort and a low-stress cohort, which are grouped after initial recruitment. Both groups undergo total resection of tumors and received 3 months of standardized treatment with radiotherapy and chemotherapy. Neither participants nor doctors but the researcher can choose which group participants are in. No one knows if one study group is better or worse than the other.
This early phase I trial tests the safety and reliability of an investigational imaging technique called quantitative oblique back illumination microscopy (qOBM) during brain surgery for detecting brain tumors and brain tumor margins in patients with glioblastoma, astrocytoma, or oligodendroglioma. Surgical margins refer to the edge or border of the tissue removed in cancer surgery. qOBM may be able to assess and reveal brain tumor surgical margins in a more safe and reliable manner.
Radiotherapy (RT) is one of the most important local treatments besides surgery, but currently, no consensus has been made regarding the optimal radiation volume for high grade gliomas. The most main growth characteristics of glioblastoma is infiltrative growth through the white matter tracts, regions along the white matter tracts especially at the direction of the main fiber bundles would have a higher risk of microscopic tumor cell dissemination. However, in current practice, recommends for the CTV definition is adding a 2 cm symmetrical margin to GTV or peritumoral edema in all directions, which hardly account for the growth characteristics of gliomas that are known from histopathological findings.
This is an ongoing Phase 2, open-label, single-center, non-randomized study of sintilimab (one anti-PD-1 antibody same as nivolumab approved in China) plus bevacizumab administered in a low dosage schedule in adult (≥ 18 years) participants with a clinical relapse or circulating tumor DNA (ctDNA)-level relapse of glioblastoma (GBM). This study has two non-comparative study groups. Both cohorts will receive the same study drug sintilimab 200mg and bevacizumab 3mg/kg every 3 weeks. A stringent two-step non-randomized process will be used to assign participants to one of the study groups. Neither participants nor doctors but the researcher can choose which group participants are in. No one knows if one study group is better or worse than the other. 60 total participants are expected to participate in this study (30 participants in each cohort). Grouping process: After enrollment, under the standard of care, participants will receive regular tumor in situ fluid (fluid within the surgical cavity, TISF) sampling for ctDNA analysis and recceive regular MRI. The researcher will study the TISF ctDNA and imaging dynamics to determine whether the tumor reaches to ctDNA-level (Cohort 1) or clinical relapse (Cohort 2). At the first step, all timely identified as ctDNA-level relapse tumors will be assigned into the Cohort 1 and receive the study drug immediately, those failed to be timely identified will be assigned into the Cohort 2 and receive the study drug after the clinical relapse. At the second step, once either group reaches the target number, the new participants will be all assigned into the other Cohort.
This study is designed to evaluate the role of Oxygen Enhanced (OE) Magnetic resonance imaging (MRI) and Blood Oxygenation Level Dependent (BOLD) MRI in detecting regions of hypoxic tumour and to evaluate their use as imaging methods to selectively deliver targeted radiotherapy to regions of aggressive disease.