000127183 001__ 127183
000127183 005__ 20230907110834.0
000127183 037__ $$aTAZ-TFM-2022-1290
000127183 041__ $$aeng
000127183 1001_ $$aSierra Torralba, María
000127183 24200 $$aAutomated sleep stage scoring using bio-signals.
000127183 24500 $$aClasificación automatizada de las fases del sueño mediante el uso de bioseñales.
000127183 260__ $$aZaragoza$$bUniversidad de Zaragoza$$c2022
000127183 506__ $$aby-nc-sa$$bCreative Commons$$c3.0$$uhttp://creativecommons.org/licenses/by-nc-sa/3.0/
000127183 520__ $$aGood quality sleep is vital for good health. It supports different physiological body functions, including immune, metabolic, and cardiovascular systems. Furthermore, adequate sleep facilitates optimal learning, memory, attention, mood, and decision-making processes. Nevertheless, sleep disorders are prevalent worldwide.<br />Sleep monitoring and scoring is crucial in the study and diagnosis of these diseases. Today,the only widely accepted method in clinical practice is the polysomnography (PSG), which is both intrusive for patients and expensive to perform for health systems. Accurate monitoring requires at least one night in a sleep laboratory and a time-consuming setup by technicians. The classification of sleep stages across the night provides information on the overall architecture of sleep, as well as the duration and proportion of the sleep stages, all of which inform the diagnosis of sleep disorders. Currently, this task is performed visually by human experts, requiring each 30-second epoch of a full night recording to be assigned a sleep stage. As a result, wating times for diagnostics are often larger than six months, depriving many patients of effective treatment and, thus, representing a pragmatic bottleneck. The main goals of this thesis are to automate such labor-intensive and routine process, leading to a great reduction in workload for clinicians, as well as addressing the increasing need for longitudinal monitoring in home environments. In order to accomplish them, an AI-powered technique is developed. This will constitute the main part of a wearable EEG monitoring device based on a new textile sensor technology, which can comfortably assess everyone’s sleep at home. For that purpose, the existing literature is explored. Machine learning algorithms and, in particular, emerging deep learning approaches have shown to be outstanding approaches. Accordingly, two different deep neural networks are proposed. After that, they are implemented and applied to sleep scoring. Their goodness is evaluated considering a wide range of datasets with very different characteristics, as well as applying diverse validation and testing methods. The results presented in this project demonstrate the validness of the models to perform real-time sleep staging with a limited number of channels in realistic settings. Moreover, one of the designed approaches in particular leads to a performance very similar to human sleep experts. Consequently, this work serves as a proof-of-concept for future sleep technology, and lays the foundation for a diverse scope of brain-computer interfaces for real-world applications.<br />
000127183 521__ $$aMáster Universitario en Robótica, Gráficos y Visión por Computador
000127183 540__ $$aDerechos regulados por licencia Creative Commons
000127183 700__ $$aMontesano del Campo, Luis$$edir.
000127183 7102_ $$aUniversidad de Zaragoza$$bInformática e Ingeniería de Sistemas$$cLenguajes y Sistemas Informáticos
000127183 8560_ $$f755180@unizar.es
000127183 8564_ $$s12633481$$uhttps://zaguan.unizar.es/record/127183/files/TAZ-TFM-2022-1290.pdf$$yMemoria (eng)
000127183 909CO $$ooai:zaguan.unizar.es:127183$$pdriver$$ptrabajos-fin-master
000127183 950__ $$a
000127183 951__ $$adeposita:2023-09-07
000127183 980__ $$aTAZ$$bTFM$$cEINA
000127183 999__ $$a20221124191111.CREATION_DATE