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Neuronal and Electrophysiological Markers of Glioma

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Date

2020-02-27

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Université d'Ottawa / University of Ottawa

Abstract

The research performed in this thesis aims to improve our understanding about one of the most malignant tumors of the human brain – glioma. From the early stages of my career I was confronted with the cruel reality of losing patients due to this devastating disease. The studies performed over the last four years involve extensive data analysis in different clinical and laboratory settings. The direct application of different analysis methods and tools in order to investigate the glioma infiltration delineation has potentially lead to direct applications of our results in the clinical setting. The overall approach of the study is based on three primary outcome measures, i.e., neuronal, electrophysiological and genetic/molecular features for distinguishing infiltrated and non-infiltrated zones within specifically peritumoral tissue (PT) and, more extensively, across the radiologically-defined boundaries of healthy, peritumoral and tumoral tissues. As such, we propose for the first time an objective demarcation and characterization of the PT and we detail how the genetic and epigenetic alterations within the tumoral and peritumoral area are linked with macroscopic functional MRI results. We also describe scale-free features (power law exponent) as well as distinct spectral features and reactivity to external stimulus in the tumoral and adjacent tissue of patients and provide novel insights in terms of glioma’s electrophysiology. The insights gained from these empirical studies further improve our understanding about the pathophysiology of this disease at micro- and macroscopic scales allowing us to envisage novel management methods for patients affected by glioma.

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Keywords

glioma, awake craniotomy, functional MRI, electrocorticography, power-law exponent, glioblastoma, glioma-related epilepsy, peritumoral tissue, neuroplasticity, genetic markers

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