Clinical Trial Finder

Inclusion Criteria:

• - Written informed consent; - Adult (18 years or older); - Diagnosed with IDH-wildtype glioblastoma, as confirmed by pathology including molecular analysis post resection/biopsy; - Referred to the outpatient clinic of the Dept.

of Radiotherapy to undergo standard treatment with radiotherapy (30x2 Gy or 15x2.67Gy) and scheduled for an MRI for radiotherapy planning.

Exclusion Criteria:

- Contraindication for (3 Tesla) MRI; - Contraindication for use of gadolinium-based contrast agent (e.g. subject having renal deficiency or known allergy); - Referred for treatment of recurrent glioblastoma; - Previous radiotherapy to the head-and-neck region; - Unable to give informed consent

Rationale: One of the fundamentals of glioblastoma management is radiotherapy, where ionizing radiation is aimed towards a specific target area in the brain to inhibit further tumor growth. As these brain tumors are notorious for their extensive tumor infiltration, where tumor grows beyond the tumor that is visible on conventional magnetic resonance imaging (MRI), this target area, defined as the clinical target volume (CTV), consists of the visible tumor plus a 1.5-cm isotropic safety margin. In the majority of cases, this unspecific CTV margin adequately covers tumor infiltration, but inevitably also includes considerable amounts of healthy tissue. Radiation-induced side-effects like headaches, nausea, fatigue and cognitive decline can substantially affect the quality of life for these patients. An opportunity arises to indirectly visualize tumor infiltration with state-of-the-art advanced MRI (aMRI) techniques, providing additional information on physiology rather than only showing anatomical information through conventional MRI. A workflow has been developed to create a CTV based on these aMRI scans (CTVaMRI) rather than an isotropic expansion. With the additional information that aMRI provides, it could be possible to more accurately define what needs to be targeted and thus minimize damage to healthy tissue. In this research, the aim is to assess the potential of integrating aMRI into radiotherapy target delineation for patients with a glioblastoma by comparing the pattern of failure (coverage of radiological tumor recurrence by the radiotherapy plan) and the expected radiation dose to organs at risk between the CTVaMRI and the 1.5-cm CTV. It is hypothesized that the CTVaMRI can result in decreased radiation dose to organs at risk, whilst having similar pattern of failure. Primary objective: To demonstrate that the probability for reduced coverage of the recurrence volume by a radiotherapy plan based on a CTVaMRI, compared to the clinical radiotherapy plan (1.5-cm CTV), is lower than 0.20. Secondary objective:

• - To illustrate a reduction in dose to organs at risk with a radiotherapy plan based on a conceptual CTVaMRI compared to the clinical radiotherapy plan (1.5-cm CTV).

• - To evaluate the synergistic information that each individual aMRI-scan provides for the identification of tumor infiltration.

• - To explore the association between pathophysiological changes on aMRI and future tumor recurrence.

Study design: In this prospective cohort study, the clinical standard MRI session used for radiotherapy planning of glioblastoma patients will be extended with aMRI techniques that assess altered oxygenation, angiogenesis and increased protein concentration. Radiation treatment (and patient follow-up) will occur according to the clinical standard, i.e. using the 1.5-cm CTV for radiotherapy planning. The aMRI-scans will be used to create a theoretical CTVaMRI and corresponding radiotherapy plan. Pattern-of-failure analysis and assessment of dose to organs at risk will be done to compare the radiotherapy plan based on the 1.5-cm CTV with the (theoretical) radiotherapy plan based on the CTVaMRI. Additionally, various theoretical CTVs based on different combinations of aMRI-scans are generated to explore the added value of the different aMRI techniques. Lastly, the signal intensities on the aMRI-scans at the site of tumor recurrence are compared with contralateral normal-appearing white matter. Study population: Patients (≥ 18 years), diagnosed with IDH-wildtype glioblastoma, as confirmed by molecular or immunohistochemistry analysis post resection/biopsy and referred to outpatient clinic of the Department of Radiotherapy to undergo standard treatment with radiotherapy. The inclusion comes to an end when 53 patients have been included. Intervention: Each patient will have an extension to their standard radiotherapy planning MRI-scan taken for regular clinical care (Brain tumor MRI protocol: ± 25 minutes). The duration of the extended MRI-scan, which includes the brain tumor MRI protocol, is ± 45 minutes. Main study parameters/endpoints: Pattern of failure and dose to organs at risk by the radiotherapy plan based on the 1.5-cm CTV and the theoretical plan created with the CTVaMRI. Nature and extent of the burden and risks associated with participation, benefit and group relatedness: The patients have the burden of prolonged scan time (+ 20 minutes, scan will last at maximum 60 minutes in total) during their standard radiotherapy planning MRI-scan. The remainder of their clinical care will not be altered: Radiotherapy will be given to these patients based on standard 1.5-cm CTVs. Follow-up will follow the clinical protocol. There will be no personal benefit for the patients in this research project.

Arms

Other: Extended MRI group

In this group, patients with a glioblastoma undergo an extended MRI-scan prior to radiotherapy.

Interventions

Diagnostic Test: - Extended MRI

The MRI-protocol before radiotherapy is extended with 20 minutes.