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Investigation of the falling asleep dynamics and its closed-loop augmentation strategy
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Li-J-2024-PhD-Thesis.pdf | Thesis | 24.48 MB | Adobe PDF | View/Open |
Title: | Investigation of the falling asleep dynamics and its closed-loop augmentation strategy |
Authors: | Li, Junheng |
Item Type: | Thesis or dissertation |
Abstract: | Sleep onset insomnia is a common sleep disturbance, particularly in the pathological ageing pop- ulation such as patients with neurodegenerative diseases and dementia. The bi-directional rela- tionship between sleep disorders and neurodegeneration makes it a novel early-stage treatment venue. Pharmacological treatments for insomnia often cause side effects and fail to show cog- nitive benefits. Novel neuromodulatory approaches, especially phase-synchronised closed-loop auditory stimulation targeting neural oscillations, have been promising candidates for enhancing deep sleep, but are yet to be explored for augmenting sleep onset. Standard sleep staging has poor temporal resolution and bad matches to subjective experi- ence, especially for patients with sleep-onset insomnia. Therefore, a better understanding of the falling asleep dynamics outside the sleep staging is necessary for better outcome measurements and closed-loop control. This thesis aims to study the falling asleep brain dynamics measured via electroencephalogram (EEG) on large sleep datasets and test the feasibility of using closed-loop auditory stimulation to augment the process. I first developed a novel feature-based statisti- cal learning approach to explore the EEG dynamics and identified several whole-brain EEG biomarkers for distinguishing the wakefulness and sleep onset states. Combined with the dy- namical systems theory, I then built a functional model to describe the continuous falling asleep transition dynamics as a catastrophic bifurcation process. Additionally, I explored the regional brain dynamics and their interactions during the falling asleep process, which provided further insights into sleep initiation. Lastly, I present a nap study to test the feasibility of phase-synchronised auditory stimulation in augmenting falling asleep, using the EEG biomarkers identified as outcome measurements. I also tested the effect of auditory-intervened naps on memory functions. The results showed a weak positive effect on associative memory. Further refined analyses are necessary to reveal mechanistic insights and guide future experimental explorations for a personalised stimulation design. |
Content Version: | Open Access |
Issue Date: | Dec-2023 |
Date Awarded: | May-2024 |
URI: | http://hdl.handle.net/10044/1/112056 |
DOI: | https://doi.org/10.25560/112056 |
Copyright Statement: | Creative Commons Attribution NonCommercial Licence |
Supervisor: | Grossman, Nir Barahona, Mauricio |
Department: | Department of Brain Sciences |
Publisher: | Imperial College London |
Qualification Level: | Doctoral |
Qualification Name: | Doctor of Philosophy (PhD) |
Appears in Collections: | Department of Brain Sciences PhD Theses |
This item is licensed under a Creative Commons License