Srimoy Chakraborty Source Confirmed

Affiliation confirmed via AI analysis of OpenAlex, ORCID, and web sources.

Federal Grant PI

Professor

University of Arkansas at Fayetteville

faculty

2 h-index 4 pubs 29 cited

Research Areas

Links

ORCID Lab Website

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OverviewAI-generated summary

Srimoy Chakraborty's research investigates the dynamics of brain activity, particularly focusing on the concept of criticality in neural systems. His work explores how scale-free behavioral dynamics are directly linked with scale-free cortical dynamics, suggesting a fundamental organizational principle in the brain. Chakraborty has examined the selective participation of single cortical neurons in neuronal avalanches and investigated whether criticality serves as a unified setpoint for brain function. His research also addresses the collapse of complexity in brain and body activity, as observed in conditions like MeCP2 disruption.

Funded by the National Institutes of Health (NIH), Chakraborty leads projects focused on understanding tunable multi-timescale cortical dynamics and investigating high-dimensional motor coding and motor dysfunction in Rett syndrome. These grants, totaling over $778,000, support his efforts to develop fundamental theories and practical tools related to brain function and neurological disorders. He collaborates with researchers at the University of Arkansas at Fayetteville, including Shree Hari Gautam, Antonio J. Fontenele, J. Samuel Sooter, and Jacob H. Barfield, with whom he has co-authored numerous publications.

Metrics

h-index: 2
Publications: 4
Citations: 29

Selected Publications

Emergent critical oscillations in motor cortex of Parkinson’s patients (2026) DOI
Two views of the brain are reconciled by a unifying principle of maximal information processing (2025) DOI
Is critical brain dynamics more prevalent than previously thought? (2025) DOI
Defining and measuring proximity to criticality (2025) DOI
Coding odor modality in piriform cortex efficiently with low-dimensional subspaces: a shared covariance decoding approach (2025) DOI
Is criticality a unified set-point of brain function? (2024) DOI
Coding odor modality in piriform cortex efficiently with low-dimensional subspaces: a Shared Covariance Decoding approach (2024) DOI
Cortex deviates from criticality during action and deep sleep: a temporal renormalization group approach (2024) DOI
Sensory input to cortex encoded on low-dimensional periphery-correlated subspaces (2023) DOI
When random variation results in functional significance (2023) DOI
Odor modality is transmitted to cortical brain regions from the olfactory bulb (2023) DOI
Editorial: Deciphering population neuronal dynamics: from theories to experiments (2023) DOI
Odor modality is transmitted to cortical brain regions from the olfactory bulb (2023) DOI
Scale-free behavioral dynamics directly linked with scale-free cortical dynamics (2023) DOI
Low dimensional criticality embedded in high dimensional awake brain dynamics (2023) DOI