TY - JOUR
T1 - From temporal to spatial topography
T2 - hierarchy of neural dynamics in higher-and lower-order networks shapes their complexity
AU - Golesorkhi, Mehrshad
AU - Gomez-Pilar, Javier
AU - Çatal, Yasir
AU - Tumati, Shankar
AU - Yagoub, Mustapha C.E.
AU - Stamatakis, Emanuel A.
AU - Northoff, Georg
N1 - Publisher Copyright:
© The Author(s) 2022. Published by Oxford University Press. All rights reserved
PY - 2022/12/15
Y1 - 2022/12/15
N2 - The brain shows a topographical hierarchy along the lines of lower-and higher-order networks. The exact temporal dynamics characterization of this lower-higher-order topography at rest and its impact on task states remains unclear, though. Using 2 functional magnetic resonance imaging data sets, we investigate lower-and higher-order networks in terms of the signal compressibility, operationalized by Lempel-Ziv complexity (LZC). As we assume that this degree of complexity is related to the slow-fast frequency balance, we also compute the median frequency (MF), an estimation of frequency distribution. We demonstrate (i) topographical differences at rest between higher-and lower-order networks, showing lower LZC and MF in the former; (ii) task-related and task-specific changes in LZC and MF in both lower-and higher-order networks; (iii) hierarchical relationship between LZC and MF, as MF at rest correlates with LZC rest-task change along the lines of lower-and higher-order networks; and (iv) causal and nonlinear relation between LZC at rest and LZC during task, with MF at rest acting as mediator. Together, results show that the topographical hierarchy of lower-and higher-order networks converges with their temporal hierarchy, with these neural dynamics at rest shaping their range of complexity during task states in a nonlinear way.
AB - The brain shows a topographical hierarchy along the lines of lower-and higher-order networks. The exact temporal dynamics characterization of this lower-higher-order topography at rest and its impact on task states remains unclear, though. Using 2 functional magnetic resonance imaging data sets, we investigate lower-and higher-order networks in terms of the signal compressibility, operationalized by Lempel-Ziv complexity (LZC). As we assume that this degree of complexity is related to the slow-fast frequency balance, we also compute the median frequency (MF), an estimation of frequency distribution. We demonstrate (i) topographical differences at rest between higher-and lower-order networks, showing lower LZC and MF in the former; (ii) task-related and task-specific changes in LZC and MF in both lower-and higher-order networks; (iii) hierarchical relationship between LZC and MF, as MF at rest correlates with LZC rest-task change along the lines of lower-and higher-order networks; and (iv) causal and nonlinear relation between LZC at rest and LZC during task, with MF at rest acting as mediator. Together, results show that the topographical hierarchy of lower-and higher-order networks converges with their temporal hierarchy, with these neural dynamics at rest shaping their range of complexity during task states in a nonlinear way.
KW - core-periphery organization
KW - lower-higher-order network topography
KW - neural complexity
KW - slow-fast frequency balance
KW - spatiotemporal neuroscience
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U2 - 10.1093/cercor/bhac042
DO - 10.1093/cercor/bhac042
M3 - Article
C2 - 35188968
AN - SCOPUS:85136755789
SN - 1047-3211
VL - 32
SP - 5637
EP - 5653
JO - Cerebral Cortex
JF - Cerebral Cortex
IS - 24
ER -