Glioblastoma is one of the most commonly observed and aggressive brain tumors. It takes its roots from star-shaped glial tissues. Glial cells support nerves, protect the BBB and, ensure continuity. Glioma is an umbrella term comprising astrocytoma, oligodendroglioma, and glioblastoma. Glioma is originated from glial tissues which are called astrocytes that gained abnormal features and shapes [1^-7].

Glioblastoma is the primary malignant brain tumor and has the worst therapy potential. World Health Organization (WHO) defines glioblastoma as the highest grade (IV grade) brain tumor [8]. Grading of diffuse glioma according to WHO 2007 was defined as Astrocytoma (Grade II), Oligodendroglioma (Grade II), Oligoastrocytoma (Grade II), Anaplastic-astrocytoma/oligodendroglioma (Grade III) and Glioblastoma (Grade IV) [8]. However, according to WHO 2016, molecular parameters in addition to histology have been initiated to use for the classification of CNS tumors. In this version, a major restructuring of the diffuse gliomas, medulloblastomas and other embryonal tumors was defined incorporating new entities based on both histology and molecular features such as glioblastoma, IDH-wildtype, and glioblastoma, IDH-mutant; diffuse midline glioma, H3 K27M–mutant; RELA fusion-positive ependymoma; medulloblastoma, WNT-activated and medulloblastoma, SHH-activated; and embryonal tumor with multilayered rosettes, C19MC-altered [9]. The incidence rate of glioma is 3.19 per 100,000 persons in the USA and a median age of 64 years. It is 1.6 times higher in males compared to females and it is uncommon in children [10].

This tumor may also attack both hemispheres of the brain [1^-3]. It may also develop high vascularization into the surrounding brain parenchyma and extensive infiltration [4^-7]. Therefore, survival is fairly poor for glioma patients. Only a few of them survive for 2.5 years following diagnosis [10]. However, early diagnosis and imaging of the disease are essential to enhance therapy efficacy and chances of survival. When compared with other techniques, non-invasive molecular imaging and advanced Magnetic Resonance Imaging (MRI) techniques possess high importance for the diagnosis of neurological diseases and alterations formed before and after tumor depending on high specificity and sensitivity. Molecular imaging provides information about monitoring of quantification of gene and protein functions, protein-protein interactions and signal transduction pathways, non-invasive detection, imaging and characterization related to the molecular pathophysiology of a specific disease [11, 12]. In this way, a more accurate and specific diagnosis of glioma can be obtained by the multidisciplinary cooperation of different branches including Nuclear Medicine, Radiology, Neurology, Neurosurgery, Oncology, and Pharmacy. To perform effective and specific molecular imaging, it is essential to establish molecular imaging probes conjugated with mAbs, antibody fragments, ligands, enzymes, substrates, peptides, proteins and markers that are specific to a receptor, amino acid or enzyme expressed in the target organ/tissue within the body. These probes can be used for imaging of the last product in the gene expression of a specific protein for binding to a target protein or markers after the radiolabeling process. These interactions are performed due to receptor-radionuclide binding or enzyme-radionuclide substrate reaction [12^-14]. Recently, the design of novel radiocontrast/contrast agents for sensitive and accurate imaging is getting popular and attractive. Molecular imaging can detect in vivo mechanisms and cellular and molecular pathways of the diseases in a dynamic a...