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Oulun yliopiston väitöskirjat




INTEGRATING NEAR-INFRARED SPECTROSCOPY TO SYNCHRONOUS MULTIMODAL NEUROIMAGING, ACTA UNIVERSITATIS OULUENSIS D Medica 1392


ISBN-13:978-952-62-1413-9 
Kieli:englanti 
Kustantaja:Oulun yliopisto 
Oppiaine:Lääketiede 
Painos:Osajulkaisuväitöskirjan yhteenveto-osa 
Painosvuosi:2016 
Sijainti:Print Tietotalo 
Sivumäärä:110 
Tekijät:KORHONEN VESA 

25.00 €

Brain disorders such as epilepsy, dementia and other mental illnesses induce increasing costs on health care systems with aging populations. The most effective treatment of these disorders would be either prevention or intervention of the disorder before irreversible damage develops. However, despite the increased interest in different brain diseases, many of them are still detected too late. One reason for this is the lack of appropriate functional imaging modality that can critically sample the targeted physiological phenomenon. Furthermore, it has been shown that one imaging modality is not enough to cover brain functionality properly; a multimodal approach is required. The main goal of this thesis was to validate near-infrared spectroscopy (NIRS) for brain measurement and to integrate it into a multimodal neuroimaging setup that can critically sample basic human physiological phenomena. A novel key element was the combined use of NIRS with ultra-fast magnetic resonance encephalography (MREG), electroencephalography (EEG), continuous non-invasive blood pressure and anesthesia monitoring as a synchronous system. This unique multimodal neuroimaging set-up with a new functional magnetic resonance imaging sequence, MREG, can sample human brain physiology at 10 Hz sampling rate without cardiorespiratory aliasing. The implemented setup was successfully used in scanning multiple patient and control populations. With the help of critical sampling rate, non-stationarity between the measured signals reflecting brain pulsations could be detected. Combined NIRS and EEG showed the capability to monitor therapeutic opening of the blood-brain barrier during treatment of central nervous system lymphoma for the first time in humans. Furthermore, our multimodal neuroimaging setup enabled the mapping of the recently described brain avalanches and glymphatic pulsation mechanisms of the brain. In conclusion, the ultra-fast multimodal laboratory with integrated NIRS offers novel and more comprehensive views on basic brain physiology. The measures from this thesis also have the potential to offer new, quantitative biomarkers for the detection of different brain disorders prior to irreversible damage.


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