Developmental Variations in Recurrent Spatiotemporal Brain Propagations from Childhood to Adulthood

Overview

Journal bioRxiv

Date 2025 Feb 20

PMID 39975397

Authors

Kyoungseob Byeon

Hyunjin Park

Shinwon Park

Jon Cluce

Kahini Mehta

Matthew Cieslak

Zaixu Cui

Seok-Jun Hong

Catie Chang

Jonathan Smallwood

Theodore D Satterthwaite

Michael P Milham

Ting Xu

Affiliations

Soon will be listed here.

Abstract

The brain undergoes profound structural and functional transformations from childhood to adolescence. Convergent evidence suggests that neurodevelopment proceeds in a hierarchical manner, characterized by heterogeneous maturation patterns across brain regions and networks. However, the maturation of the intrinsic spatiotemporal propagations of brain activity remains largely unexplored. This study aims to bridge this gap by delineating spatiotemporal propagations from childhood to early adulthood. By leveraging a recently developed approach that captures time-lag dynamic propagations, we characterized intrinsic dynamic propagations along three axes: sensory-association (S-A), 'task-positive' to default networks (TP-D), and somatomotor-visual (SM-V) networks, which progress towards adult-like brain dynamics from childhood to early adulthood. Importantly, we demonstrated that as participants mature, there is a prolonged occurrence of the S-A and TP-D propagation states, indicating that they spend more time in these states. Conversely, the prevalence of SM-V propagation states declines during development. Notably, top-down propagations along the S-A axis exhibited an age-dependent increase in occurrence, serving as a superior predictor of cognitive scores compared to bottom-up S-A propagation. These findings were replicated across two independent cohorts (N = 677 in total), emphasizing the robustness and generalizability of these findings. Our results provide new insights into the emergence of adult-like functional dynamics during youth and their role in supporting cognition.

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