Cortico-cortical Communication Dynamics

doi:10.3389/978-2-88919-288-5

Cited by 2 publications

(2 citation statements)

References 107 publications

(169 reference statements)

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“…For a channel communicating at 0.1% distortion (and across all distortions; Supporting Information Figure S6C ), biasing structural edge weights by the biological properties of metabolic and electrical signaling resulted in more efficient communication by reducing the number of redundant random walkers required ( Figure 4C ; t metabolic = 20.87, bootstrap 95% CI [18.72, 23.14], df = 1993.9; t electrical = 295.93, bootstrap 95% CI [281.19, 312.76], df = 1225.9, p < 0.001). While both metabolic and electrical signaling supported more efficient communication, electrical signaling was more efficient than metabolic signaling ( Deco et al, 2014 ; Sterling & Laughlin, 2015 ). Compared to rewired null networks preserving the degree sequence ( Supporting Information Figure S6D ), structural topology and metabolic resources support communication that prioritizes fidelity ( t topological,degree-preserving (2074.4) = 121.02, p < 0.001; t metabolic,degree-preserving (2025.8) = 87.78, p < 0.001), while myelination supports communication that prioritizes compression efficiency ( t electrical,degree-preserving (1208.3) = −122.62, p < 0.001).…”

Section: Resultsmentioning

confidence: 99%

“…Second, it is well known that brain signaling relies extensively on metabolic diffusion and devotes much of its metabolic resources to maintaining a chemical balance that supports neuron firing ( Attwell & Laughlin, 2001 ; Sterling & Laughlin, 2015 ). At the longer distances of the connectome, myelin in the white matter and cerebral cortex supports the speed and efficiency of electrical signaling in subcortical fiber tracts and in cortico-cortical communication ( Barbas & Rempel-Clower, 1997 ; Deco, Roland, & Hilgetag, 2014 ; Laughlin, 2001 ). Hence, modifying the connectome to bias random walk dynamics according to metabolic resources and myelin mimics biological investments in communication efficiency.…”

Section: Resultsmentioning

confidence: 99%

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Efficient coding in the economics of human brain connectomics

Zhou

Lynn

Cui

et al. 2022

Network Neuroscience

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In systems neuroscience, most models posit that brain regions communicate information under constraints of efficiency. Yet, evidence for efficient communication in structural brain networks remains sparse. The principle of efficient coding proposes that the brain transmits maximal information in a metabolically economical or compressed form to improve future behavior. To determine how structural connectivity supports efficient coding, we develop a theory specifying minimum rates of message transmission between brain regions to achieve an expected fidelity, and we test five predictions from the theory based on random walk communication dynamics. In doing so, we introduce the metric of compression efficiency, which quantifies the trade-off between lossy compression and transmission fidelity in structural networks. In a large sample of youth (n = 1,042; age 8–23 years), we analyze structural networks derived from diffusion weighted imaging and metabolic expenditure operationalized using cerebral blood flow. We show that structural networks strike compression efficiency trade-offs consistent with theoretical predictions. We find that compression efficiency prioritizes fidelity with development, heightens when metabolic resources and myelination guide communication, explains advantages of hierarchical organization, links higher input fidelity to disproportionate areal expansion, and shows that hubs integrate information by lossy compression. Lastly, compression efficiency is predictive of behavior—beyond the conventional network efficiency metric—for cognitive domains including executive function, memory, complex reasoning, and social cognition. Our findings elucidate how macroscale connectivity supports efficient coding, and serve to foreground communication processes that utilize random walk dynamics constrained by network connectivity.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Efficient coding in the economics of human brain connectomics

Zhou

Lynn

Cui

et al. 2022

Network Neuroscience

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Efficient Coding in the Economics of Human Brain Connectomics

Zhou

Lynn

Cui

et al. 2020

Preprint

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In systems neuroscience, most models posit that brain regions communicate information under constraints of efficiency. Yet, metabolic and information transfer efficiency across structural networks are not understood. In a large cohort of youth, we find metabolic costs associated with structural path strengths supporting information diffusion. Metabolism is balanced with the coupling of structures supporting diffusion and network modularity. To understand efficient network communication, we develop a theory specifying minimum rates of message diffusion that brain regions should transmit for an expected fidelity, and we test five predictions from the theory. We introduce compression efficiency, which quantifies differing trade-offs between lossy compression and communication fidelity in structural networks. Compression efficiency evolves with development, heightens when metabolic gradients guide diffusion, constrains network complexity, explains how rich-club hubs integrate information, and correlates with cortical areal scaling, myelination, and speed-accuracy trade-offs. Our findings elucidate how network structures and metabolic resources support efficient neural communication.

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Cortico-cortical Communication Dynamics

Cited by 2 publications

References 107 publications

Efficient coding in the economics of human brain connectomics

Efficient coding in the economics of human brain connectomics

Efficient Coding in the Economics of Human Brain Connectomics

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