In and Out of Criticality? State-Dependent Scaling in the Rat Visual Cortex

Castro, Daniel M.; Feliciano, Thaís; de Vasconcelos, Nivaldo A. P.; Soares-Cunha, Carina; Coimbra, Bárbara; Rodrigues, Ana João; Carelli, Pedro V.; Copelli, Mauro

doi:10.1103/prxlife.2.023008

PRX Life

2024

DOI: 10.1103/prxlife.2.023008

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In and Out of Criticality? State-Dependent Scaling in the Rat Visual Cortex

Daniel M. Castro,

Thaís Feliciano,

Nivaldo A. P. de Vasconcelos

et al.

Abstract: The presumed proximity to a critical point is believed to endow the brain with scale-invariant statistics, which are thought to confer various functional advantages in terms of its information processing, storage, and transmission capabilities. To assess the relationship between scaling and cortical states, we apply a phenomenological renormalization group analysis to 3-h spiking data recordings from the urethane-anesthetized rat's visual cortex. Under this type of anesthesia, cortical states dynamically shift… Show more

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Tracking the Distance to Criticality in Systems with Unknown Noise

Harris,

Gollo,

Fulcher

2024

Phys. Rev. X

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Many real-world systems undergo abrupt changes in dynamics as they move across critical points, often with dramatic and irreversible consequences. Much existing theory on identifying the time-series signatures of nearby critical points, such as increased signal variance and slower timescales, is derived from analytically tractable systems, typically considering the case of fixed, low-amplitude noise. However, real-world systems are often corrupted by unknown levels of noise that can distort these temporal signatures. Here we aim to develop noise-robust indicators of the distance to criticality (DTC) for systems affected by dynamical noise in two cases: when the noise amplitude is either fixed or is unknown and variable across recordings. We present a highly comparative approach to this problem that compares the ability of over 7000 candidate time-series features to track the DTC in the vicinity of a supercritical Hopf bifurcation. Our method recapitulates existing theory in the fixed-noise case, highlighting conventional time-series features that accurately track the DTC. But in the variable-noise setting, where these conventional indicators perform poorly, we highlight new types of high-performing time-series features and show that their success is accomplished by capturing the shape of the invariant density (which depends on both the DTC and the noise amplitude) relative to the spread of fast fluctuations (which depends on the noise amplitude). We introduce a new high-performing time-series statistic, the rescaled autodensity (RAD), that combines these two algorithmic components. We then use RAD to provide new evidence that brain regions higher in the visual hierarchy are positioned closer to criticality, supporting existing hypotheses about patterns of brain organization that are not detected using conventional metrics of the DTC. Our results demonstrate how large-scale algorithmic comparison can yield theoretical insights that can motivate new theory and interpretable algorithms for solving important real-world problems. Published by the American Physical Society 2024

show abstract

Tracking the Distance to Criticality in Systems with Unknown Noise

Harris,

Gollo,

Fulcher

2024

Phys. Rev. X

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show abstract

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In and Out of Criticality? State-Dependent Scaling in the Rat Visual Cortex

Cited by 1 publication

References 80 publications

Tracking the Distance to Criticality in Systems with Unknown Noise

Tracking the Distance to Criticality in Systems with Unknown Noise

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