Direct brain recordings reveal continuous encoding of structure in random stimuli

JULIAN, FUHRER; KYRRE, GLETTE; JUGOSLAV IVANOVIC; PÅL GUNNAR LARSSON; TRISTAN BEKINSCHTEIN; TRISTAN BEKINSCHTEIN; SILVIA KOCHEN; ROBERT T. KNIGHT; , JIM TØRRESEN; ANNE-KRISTIN SOLBAKK; TOR ENDESTAD; ALEJANDRO BLENKMANN

bioRxiv

bioRxiv

Lugar: OSLO; Año: 2021 p. 1 - 14

2692-8205

The brain excels at processing sensory input, even in rich or chaotic environments. Mounting evidence attributes this to the creation of sophisticated internal models of the environment that drawon statistical structures in the unfolding sensory input. Understanding how and where this modeling takes place is a core question in statistical learning. It is unknown how this modeling applies torandom sensory signals. Here, we identify conditional relations, through transitional probabilities, asan implicit structure supporting the encoding of a random auditory stream. We evaluate this representation using intracranial electroencephalography recordings by applying information-theoreticalprinciples to high-frequency activity (75 to 145 Hz). We demonstrate how the brain continuously encodes conditional relations between random stimuli in a network outside of the auditory system following a hierarchical organization including temporal, frontal and hippocampal regions. Our resultshighlight that hierarchically organized brain areas continuously attempt to order incoming information by maintaining a probabilistic representation of the sensory input, even under random stimulipresentation.