Quantifying arousal and awareness in altered states of consciousness using interpretable deep learning.
Minji LeeLeandro R D SanzAlice BarraAudrey WolffJaakko O NieminenMelanie BolyMario RosanovaCasarotto SilviaOlivier BodartJitka AnnenAurore ThibautRajanikant PandaVincent L BonhommeMarcello MassiminiGiulio TononiSteven LaureysOlivia GosseriesSeong-Whan LeePublished in: Nature communications (2022)
Consciousness can be defined by two components: arousal (wakefulness) and awareness (subjective experience). However, neurophysiological consciousness metrics able to disentangle between these components have not been reported. Here, we propose an explainable consciousness indicator (ECI) using deep learning to disentangle the components of consciousness. We employ electroencephalographic (EEG) responses to transcranial magnetic stimulation under various conditions, including sleep (n = 6), general anesthesia (n = 16), and severe brain injury (n = 34). We also test our framework using resting-state EEG under general anesthesia (n = 15) and severe brain injury (n = 34). ECI simultaneously quantifies arousal and awareness under physiological, pharmacological, and pathological conditions. Particularly, ketamine-induced anesthesia and rapid eye movement sleep with low arousal and high awareness are clearly distinguished from other states. In addition, parietal regions appear most relevant for quantifying arousal and awareness. This indicator provides insights into the neural correlates of altered states of consciousness.
Keyphrases
- brain injury
- resting state
- functional connectivity
- subarachnoid hemorrhage
- deep learning
- transcranial magnetic stimulation
- cerebral ischemia
- working memory
- physical activity
- high frequency
- sleep quality
- early onset
- artificial intelligence
- machine learning
- drug induced
- high glucose
- convolutional neural network
- depressive symptoms
- oxidative stress
- pain management
- endothelial cells
- blood brain barrier
- chronic pain