Studying, Measuring and Altering Consciousness through information theory in the electrical brain
ProjectWhat is consciousness? Can it be measured? While humankind has struggled with these questions for millennia, our project will focus on more modest but nonetheless ambitious and related goals. Inspired by recent developments in neuroscience and the potential role of fundamental concepts such as information integration and algorithmic complexity, we will study, model, quantify, and alter observable aspects of consciousness. Our vision is that consciousness will someday be electromagnetically measured and altered, and that the associated needed insights will prove crucial to the development cognitive sciences.
The conceptual framework of the project rests on information theoretic developments that link consciousness to the amount of information that a physical system can represent and generate as an integrated whole, and from the related idea that consciousness can be quantified by metrics reflecting information processing and representation complexity.
Supported by computational neuroscience models, we aim to create non-invasive consciousness-probing technologies integrating electro- and magneto-encephalography, peripheral and non-invasive brain stimulation (NIBS) with advanced techniques to analyse brain activity ¿ including functional and effective connectivity. Based on the derived brain activity metrics, we will explore intervention, ie the use of NIBS to alter consciousness. To achieve these goals we will pursue computational neuroscience models and human studies ¿ in perception, sleep, anaesthesia, locked-in syndrome, disorders of consciousness, and in utero ¿ supported by machine learning to disentangle the essential aspects of consciousness.
The project will also explore the ethical implications of such technologies and the prospects for clinical translation. If successful, this paradigm-shifting work will have profound social and clinical impact and provide key insights in fundamental neuroscience and artificial cognition research.
The conceptual framework of the project rests on information theoretic developments that link consciousness to the amount of information that a physical system can represent and generate as an integrated whole, and from the related idea that consciousness can be quantified by metrics reflecting information processing and representation complexity.
Supported by computational neuroscience models, we aim to create non-invasive consciousness-probing technologies integrating electro- and magneto-encephalography, peripheral and non-invasive brain stimulation (NIBS) with advanced techniques to analyse brain activity ¿ including functional and effective connectivity. Based on the derived brain activity metrics, we will explore intervention, ie the use of NIBS to alter consciousness. To achieve these goals we will pursue computational neuroscience models and human studies ¿ in perception, sleep, anaesthesia, locked-in syndrome, disorders of consciousness, and in utero ¿ supported by machine learning to disentangle the essential aspects of consciousness.
The project will also explore the ethical implications of such technologies and the prospects for clinical translation. If successful, this paradigm-shifting work will have profound social and clinical impact and provide key insights in fundamental neuroscience and artificial cognition research.