TY - UNPB
T1 - Evidence for increased parallel information transmission in human brain networks compared to macaques and mice
AU - Griffa, Alessandra
AU - Mach, Mathieu
AU - Dedelley, Julien
AU - Gutierrez-Barragan, Daniel
AU - Gozzi, Alessandro
AU - Allali, Gilles
AU - Grandjean, Joanes
AU - Van De Ville, Dimitri
AU - Amico, Enrico
PY - 2023/10/31
Y1 - 2023/10/31
N2 - Brain communication, defined as information transmission through white-matter connections, is at the foundation of the brain’s computational capacities that subtend almost all aspects of behavior: from sensory perception shared across mammalian species, to complex cognitive functions in humans. How did communication strategies in macroscale brain networks adapted across evolution to accomplish increasingly complex functions? By applying a graph- and information-theory approach to assess information-related pathways in mouse, macaque and human brains, we show a brain communication gap between selective information transmission in non-human mammals, where brain regions share information through single polysynaptic pathways, and parallel information transmission in humans, where regions share information through multiple parallel pathways. In humans, parallel transmission acts as a major connector between unimodal and transmodal systems. The layout of information-related pathways is unique to individuals across different mammalian species, pointing at the individual-level specificity of information routing architecture. Our work provides evidence that different communication patterns are tied to the evolution of mammalian brain networks.
AB - Brain communication, defined as information transmission through white-matter connections, is at the foundation of the brain’s computational capacities that subtend almost all aspects of behavior: from sensory perception shared across mammalian species, to complex cognitive functions in humans. How did communication strategies in macroscale brain networks adapted across evolution to accomplish increasingly complex functions? By applying a graph- and information-theory approach to assess information-related pathways in mouse, macaque and human brains, we show a brain communication gap between selective information transmission in non-human mammals, where brain regions share information through single polysynaptic pathways, and parallel information transmission in humans, where regions share information through multiple parallel pathways. In humans, parallel transmission acts as a major connector between unimodal and transmodal systems. The layout of information-related pathways is unique to individuals across different mammalian species, pointing at the individual-level specificity of information routing architecture. Our work provides evidence that different communication patterns are tied to the evolution of mammalian brain networks.
U2 - 10.1101/2022.05.09.491115
DO - 10.1101/2022.05.09.491115
M3 - Preprint
BT - Evidence for increased parallel information transmission in human brain networks compared to macaques and mice
PB - bioRxiv
ER -