Clinical Trials Logo

Clinical Trial Summary

Relapsed GBMs have a life expectancy of a few months and re-radiation has proven to be safe in terms of toxicity and effective in increasing OS. One of our studies [Ciammella P, 2013, 8:222] reported a median survival of 9.5 months in patients with recurrent GBM and treated with stereotactic radiotherapy with a total dose of 25 Gy in 5 consecutive sessions, in which the dose was prescribed to 70% isodose with a homogeneous gradient towards the center of the target volume. The identification with functional imaging of specific areas with higher tumor cell density, and the possibility of delivering precisely, thanks to the most advanced therapy units, different doses to the different sub-volumes, can lead to an increase in the maximum dose that can be delivered at the expense of the most aggressive areas (with a greater effect on the tumor), compared to smaller doses in areas with lower signal alteration. This selectivity of the doses should allow an increase in the efficacy of the therapy and therefore a hypothetical increase in local control, compared to a radio-induced toxicity on the surrounding healthy tissues almost comparable to that achieved with the previous hypofractionated treatments [Ciammella P, 2013]. In fact, delivering many high doses to the entire volume would result in an excess of radio-induced necrosis within the irradiated regions with high dose, as well as the impossibility of minimizing the doses on healthy areas and / or on non-neoplastic critical areas keeping them at internal dose ranges related to minimal and acceptable toxicity levels. Since there are no studies providing clear indications on the acute and late toxicity of irradiated healthy tissues that have already been the subject of a first course of radiotherapy (STUPP), the choice of safety is the primary objective of the study.


Clinical Trial Description

It is an exploratory, prospective, experimental, monocentric study. Having identified a main safety endpoint (toxicity of radiotherapy treatment) and in the absence of data currently available from previous studies and useful for sizing the sample, the sample is defined according to opportunity and feasibility criteria, (12 cases), with a drawing (3 cases + 3 cases + 6 cases) which provides for two intermediate safety assessment steps one month after the end of the third and sixth patient treatment. The study will be continued only in case of positive evaluation of both steps. For each individual patient the treatment is considered completed if: a) the experimental radiotherapy treatment has been completed; b) the first follow-up radiological assessment (NMR) was performed; c) the study treatment was prematurely interrupted due to lack of efficacy (documented disease progression) or unacceptable toxicity. - Treatment: the treatment foreseen by the protocol foresees the planning and the execution of a hypofractionated radiotherapy (RT) treatment, administered in 5 daily sessions, with intensity modulated technique and inhomogeneous distribution of the dose guided by the diffusion images obtained with magnetic resonance (RM). The radiotherapy treatment must start within 7 days from the date of execution of the centering MRI which will include both the classic morphological sequences with administration of contrast medium and functional ones. In selected cases and according to clinical judgment it will be possible to request the revision of the anatomopathological and radiological findings. - Radiation technique: for each patient, a radiotherapy treatment plan will be performed with conformed techniques such as intensity-modulated radiotherapy (IMRT) with dose redistribution: dose-painting. - Positioning and immobilization of the patient: the patient must be treated in a supine position. The arms must be positioned along the body. The use of a knee support is recommended. The garment will be immobilized with a thermoplastic mask and corresponding neck rest supports. - TC and planning RM: the planning CT should be acquired possibly with reduced layer thickness that contains the entire volume of the skull and the upper part of the shoulders. This is done to allow the possibility of planning non-coplanar type treatments. The last follow-up MRI, or the radiotherapy centering RM, composed of standard and functional sequences, is used for planning, in addition to those that the neuroradiologist will have considered useful to better characterize the clinical case under examination. More details on this are described in the Technical Annex. - Target volume and organs at risk (OAR): the following target volumes must be identified: • Gross tumor volume (GTV): it is defined using and combining the conventional and advanced sequences of the NMR. • Planning target volume (PTV): it is represented by the GTV with three-dimensional expansion between 0 and 5 mm according to the problems highlighted during the tumor segmentation phase. See the Technical Annex in this regard. - The following risky organs (OAR) must be identified: • Optical nerves: the definition of the related planning risk volume is also suggested (PRV: organ at risk with three-dimensional expansion; this margin must be chosen taking into account the acquisition thickness of the centering TC and the chosen GTV-PTV expansion margin). • chiasm. We also suggest the definition of the relative PRV (organ at risk with three-dimensional expansion; this margin must be chosen taking into account the acquisition thickness of the centering CT and the chosen GTV-PTV expansion margin). • retinas. We also suggest the definition of the relative PRV (organ at risk with three-dimensional expansion; this margin must be chosen taking into account the acquisition thickness of the centering CT and the chosen GTV-PTV expansion margin). Alternatively the eye globes can be surrounded. • Encefalic trunk. - The following secondary OARs must be identified: • Lenses / Crystalline. We also suggest the definition of the relative PRV (organ at risk with three-dimensional expansion; this margin must be chosen taking into account the acquisition thickness of the centering CT and the chosen GTV-PTV expansion margin). • Healthy brain tissue. It is represented by the encephalon volume minus the PTV. • Screw. We also suggest the definition of the relative PRV (organ at risk with three-dimensional expansion; this margin must be chosen taking into account the acquisition thickness of the centering CT and the chosen GTV-PTV expansion margin). - Dose prescription: i) Dose to the target: the prescription dose foresees a minimum dose of 30 Gy (6 Gy per session) for the areas with the highest ADC with a gradual increase in the dose of the lower ADC areas. The maximum hypothesized dose is 50 Gy, with a dose of 10 Gy per session to no more than 1cc of the irradiated brain tissue. The treatment plan, however, will be processed in the following order of priority: 1. Compliance with dose limits for primary OARs. 2. PTV coverage. 3. Compliance with dose limits for secondary OARs. - Dose limits for primary risk organs: in the scientific literature there are various studies that indicate the dose limits of the organs at risk for brain radiation treatments. ;


Study Design


Related Conditions & MeSH terms


NCT number NCT04610229
Study type Interventional
Source Arcispedale Santa Maria Nuova-IRCCS
Contact
Status Completed
Phase N/A
Start date February 1, 2016
Completion date August 26, 2019

See also
  Status Clinical Trial Phase
Recruiting NCT05664243 - A Phase 1b / 2 Drug Resistant Immunotherapy With Activated, Gene Modified Allogeneic or Autologous γδ T Cells (DeltEx) in Combination With Maintenance Temozolomide in Subjects With Recurrent or Newly Diagnosed Glioblastoma Phase 1/Phase 2
Completed NCT02768389 - Feasibility Trial of the Modified Atkins Diet and Bevacizumab for Recurrent Glioblastoma Early Phase 1
Recruiting NCT05635734 - Azeliragon and Chemoradiotherapy in Newly Diagnosed Glioblastoma Phase 1/Phase 2
Completed NCT03679754 - Evaluation of Ad-RTS-hIL-12 + Veledimex in Subjects With Recurrent or Progressive Glioblastoma, a Substudy to ATI001-102 Phase 1
Completed NCT01250470 - Vaccine Therapy and Sargramostim in Treating Patients With Malignant Glioma Phase 1
Terminated NCT03927222 - Immunotherapy Targeted Against Cytomegalovirus in Patients With Newly-Diagnosed WHO Grade IV Unmethylated Glioma Phase 2
Recruiting NCT03897491 - PD L 506 for Stereotactic Interstitial Photodynamic Therapy of Newly Diagnosed Supratentorial IDH Wild-type Glioblastoma Phase 2
Active, not recruiting NCT03587038 - OKN-007 in Combination With Adjuvant Temozolomide Chemoradiotherapy for Newly Diagnosed Glioblastoma Phase 1
Completed NCT01922076 - Adavosertib and Local Radiation Therapy in Treating Children With Newly Diagnosed Diffuse Intrinsic Pontine Gliomas Phase 1
Recruiting NCT04391062 - Dose Finding for Intraoperative Photodynamic Therapy of Glioblastoma Phase 2
Active, not recruiting NCT03661723 - Pembrolizumab and Reirradiation in Bevacizumab Naïve and Bevacizumab Resistant Recurrent Glioblastoma Phase 2
Active, not recruiting NCT02655601 - Trial of Newly Diagnosed High Grade Glioma Treated With Concurrent Radiation Therapy, Temozolomide and BMX-001 Phase 2
Completed NCT02206230 - Trial of Hypofractionated Radiation Therapy for Glioblastoma Phase 2
Completed NCT03493932 - Cytokine Microdialysis for Real-Time Immune Monitoring in Glioblastoma Patients Undergoing Checkpoint Blockade Phase 1
Terminated NCT02709889 - Rovalpituzumab Tesirine in Delta-Like Protein 3-Expressing Advanced Solid Tumors Phase 1/Phase 2
Recruiting NCT06058988 - Trastuzumab Deruxtecan (T-DXd) for People With Brain Cancer Phase 2
Completed NCT03018288 - Radiation Therapy Plus Temozolomide and Pembrolizumab With and Without HSPPC-96 in Newly Diagnosed Glioblastoma (GBM) Phase 2
Withdrawn NCT03980249 - Anti-Cancer Effects of Carvedilol With Standard Treatment in Glioblastoma and Response of Peripheral Glioma Circulating Tumor Cells Early Phase 1
Not yet recruiting NCT04552977 - A Trail of Fluzoparil in Combination With Temozolomide in Patients With Recurrent Glioblastoma Phase 2
Terminated NCT02905643 - Discerning Pseudoprogression vs True Tumor Growth in GBMs