A synergistic core for human brain evolution and cognition

Luppi, Andrea I.; Mediano, Pedro A. M.; Rosas, Fernando; Holland, Negin; Fryer, Tim D.; O’Brien, John T.; Rowe, James B.; Menon, David K.; Bor, Daniel; Stamatakis, Emmanuel A.

doi:10.1038/s41593-022-01070-0

Cited by 119 publications

(172 citation statements)

References 125 publications

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“…Rather, the goal is to offer a crisp window into the types of insights that can emerge. We draw preferentially on our own work out of convenience, but this work in turn was inspired by, and complements, other exemplary lines of empirical work (for examples, see [ 5 , 21 , 35 , 41 , 42 , 43 , 44 , 45 , 46 ]).…”

Section: Pid In Actionmentioning

confidence: 99%

“…A recent multi-target generalization of the PID, termed integrated information decomposition (

ID) [ 69 , 70 ] has been proposed, which opens the door to a much wider range of possible analyses than is possible with a single-target PID analysis.

ID analysis of fMRI data has found changes in the flow of synergistic information associated with loss of consciousness [ 46 , 71 ] and the genetic architecture of the brain [ 44 ]. A recently introduced “temporal redundancy function” (

), coupled with a

ID analysis, led to the discovery of a set of sixteen distinct information dynamics associated with the temporal evolution of pairs of interacting neurons, many of which were previously unknown [ 45 ].…”

Section: Future Directionsmentioning

confidence: 99%

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Revealing the Dynamics of Neural Information Processing with Multivariate Information Decomposition

Newman

Varley

Parakkattu

et al. 2022

Entropy

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The varied cognitive abilities and rich adaptive behaviors enabled by the animal nervous system are often described in terms of information processing. This framing raises the issue of how biological neural circuits actually process information, and some of the most fundamental outstanding questions in neuroscience center on understanding the mechanisms of neural information processing. Classical information theory has long been understood to be a natural framework within which information processing can be understood, and recent advances in the field of multivariate information theory offer new insights into the structure of computation in complex systems. In this review, we provide an introduction to the conceptual and practical issues associated with using multivariate information theory to analyze information processing in neural circuits, as well as discussing recent empirical work in this vein. Specifically, we provide an accessible introduction to the partial information decomposition (PID) framework. PID reveals redundant, unique, and synergistic modes by which neurons integrate information from multiple sources. We focus particularly on the synergistic mode, which quantifies the “higher-order” information carried in the patterns of multiple inputs and is not reducible to input from any single source. Recent work in a variety of model systems has revealed that synergistic dynamics are ubiquitous in neural circuitry and show reliable structure–function relationships, emerging disproportionately in neuronal rich clubs, downstream of recurrent connectivity, and in the convergence of correlated activity. We draw on the existing literature on higher-order information dynamics in neuronal networks to illustrate the insights that have been gained by taking an information decomposition perspective on neural activity. Finally, we briefly discuss future promising directions for information decomposition approaches to neuroscience, such as work on behaving animals, multi-target generalizations of PID, and time-resolved local analyses.

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Section: Pid In Actionmentioning

confidence: 99%

“…A recent multi-target generalization of the PID, termed integrated information decomposition (

ID) [ 69 , 70 ] has been proposed, which opens the door to a much wider range of possible analyses than is possible with a single-target PID analysis.

), coupled with a

Section: Future Directionsmentioning

confidence: 99%

Revealing the Dynamics of Neural Information Processing with Multivariate Information Decomposition

Newman

Varley

Parakkattu

et al. 2022

Entropy

View full text Add to dashboard Cite

show abstract

“…As an example of the former, ΦID has been used to show that existing quantifications of integrated information (and related quantities such as 'causal density' [90]) are not capturing a unique type of information dynamics, but rather conflating multiple ones. Following this finding, a revised version of Φ-denoted by Φ R -has been proposed, which has been shown to capture various important aspects of a broad range of complex systems [91,92], and be more precise than Φ in finding or detecting specific differences between conscious and unconscious dynamics of the human brain [93].…”

Section: Applications Of φId: Integrated Information Decompositionmentioning

confidence: 99%

“…More broadly, ΦID is enabling novel ways to conceptualize brain function, by providing an information-resolved FC that complements the time-resolved perspective [93]. Empirical analyses based on fMRI data have shown a role for redundancy in ensuring robust input/output communication channels, as is especially prominent in somatomotor and sensory regions.…”

Section: Applications Of φId: Integrated Information Decompositionmentioning

confidence: 99%

“…Empirical analyses based on fMRI data have shown a role for redundancy in ensuring robust input/output communication channels, as is especially prominent in somatomotor and sensory regions. By contrast, synergy is related to efficient communication in highorder association cortices, and supports humans' sophisticated cognitive functions, being more prominent in evolutionarily expanded regions of the cerebral cortex [93]. The further identification of specific molecular, cytoarchitectonic and metabolic profiles suggests that in the close future we may be able to embody information processing properties into tissues' biophysical properties, a critical step towards supporting the biological plausibility of intrinsic computation in the brain.…”

Section: Applications Of φId: Integrated Information Decompositionmentioning

confidence: 99%

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May the 4C's be with you: an overview of complexity-inspired frameworks for analysing resting-state neuroimaging data

Hancock

Rosas

Mediano

et al. 2022

J. R. Soc. Interface.

Self Cite

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Competing and complementary models of resting-state brain dynamics contribute to our phenomenological and mechanistic understanding of whole-brain coordination and communication, and provide potential evidence for differential brain functioning associated with normal and pathological behaviour. These neuroscientific theories stem from the perspectives of physics, engineering, mathematics and psychology and create a complicated landscape of domain-specific terminology and meaning, which, when used outside of that domain, may lead to incorrect assumptions and conclusions within the neuroscience community. Here, we review and clarify the key concepts of connectivity, computation, criticality and coherence—the 4C's—and outline a potential role for metastability as a common denominator across these propositions. We analyse and synthesize whole-brain neuroimaging research, examined through functional magnetic imaging, to demonstrate that complexity science offers a principled and integrated approach to describe, and potentially understand, macroscale spontaneous brain functioning.

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Viscous dynamics associated with hypoexcitation and structural disintegration in neurodegeneration via generative whole‐brain modeling

Coronel‐Oliveros,

Gómez,

Ranasinghe

et al. 2024

Alzheimer's & Dementia

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INTRODUCTIONAlzheimer's disease (AD) and behavioral variant frontotemporal dementia (bvFTD) lack mechanistic biophysical modeling in diverse, underrepresented populations. Electroencephalography (EEG) is a high temporal resolution, cost‐effective technique for studying dementia globally, but lacks mechanistic models and produces non‐replicable results.METHODSWe developed a generative whole‐brain model that combines EEG source‐level metaconnectivity, anatomical priors, and a perturbational approach. This model was applied to Global South participants (AD, bvFTD, and healthy controls).RESULTSMetaconnectivity outperformed pairwise connectivity and revealed more viscous dynamics in patients, with altered metaconnectivity patterns associated with multimodal disease presentation. The biophysical model showed that connectome disintegration and hypoexcitability triggered altered metaconnectivity dynamics and identified critical regions for brain stimulation. We replicated the main results in a second subset of participants for validation with unharmonized, heterogeneous recording settings.DISCUSSIONThe results provide a novel agenda for developing mechanistic model‐inspired characterization and therapies in clinical, translational, and computational neuroscience settings.

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A synergistic core for human brain evolution and cognition

Cited by 119 publications

References 125 publications

Revealing the Dynamics of Neural Information Processing with Multivariate Information Decomposition

Revealing the Dynamics of Neural Information Processing with Multivariate Information Decomposition

May the 4C's be with you: an overview of complexity-inspired frameworks for analysing resting-state neuroimaging data

Viscous dynamics associated with hypoexcitation and structural disintegration in neurodegeneration via generative whole‐brain modeling

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