Decoding neuronal networks: A Reservoir Computing approach for predicting connectivity and functionality

Ilya Auslender; Giorgio Letti; Yasaman Heydari; Clara Zaccaria; Lorenzo Pavesi

doi:10.1016/j.neunet.2024.107058

Decoding neuronal networks: A Reservoir Computing approach for predicting connectivity and functionality

Ilya Auslender, Giorgio Letti, Yasaman Heydari, Clara Zaccaria, Lorenzo Pavesi

Research output: Contribution to journal › Article › peer-review

Abstract

In this study, we address the challenge of analyzing electrophysiological measurements in neuronal networks. Our computational model, based on the Reservoir Computing Network (RCN) architecture, deciphers spatio-temporal data obtained from electrophysiological measurements of neuronal cultures. By reconstructing the network structure on a macroscopic scale, we reveal the connectivity between neuronal units. Notably, our model outperforms common methods such as Cross-Correlation, Transfer-Entropy, and a recently developed related algorithm in predicting the network's connectivity map. Furthermore, we experimentally validate its ability to forecast network responses to specific inputs, including localized optogenetic stimuli.

Original language	English
Article number	107058
Journal	Neural Networks
Volume	184
DOIs	https://doi.org/10.1016/j.neunet.2024.107058
State	Published - 1 Apr 2025
Externally published	Yes

Keywords

Electrophysiological data
Neural models
Reservoir computing

ASJC Scopus subject areas

Cognitive Neuroscience
Artificial Intelligence

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10.1016/j.neunet.2024.107058

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title = "Decoding neuronal networks: A Reservoir Computing approach for predicting connectivity and functionality",

abstract = "In this study, we address the challenge of analyzing electrophysiological measurements in neuronal networks. Our computational model, based on the Reservoir Computing Network (RCN) architecture, deciphers spatio-temporal data obtained from electrophysiological measurements of neuronal cultures. By reconstructing the network structure on a macroscopic scale, we reveal the connectivity between neuronal units. Notably, our model outperforms common methods such as Cross-Correlation, Transfer-Entropy, and a recently developed related algorithm in predicting the network's connectivity map. Furthermore, we experimentally validate its ability to forecast network responses to specific inputs, including localized optogenetic stimuli.",

keywords = "Electrophysiological data, Neural models, Reservoir computing",

author = "Ilya Auslender and Giorgio Letti and Yasaman Heydari and Clara Zaccaria and Lorenzo Pavesi",

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year = "2025",

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AU - Auslender, Ilya

AU - Letti, Giorgio

AU - Heydari, Yasaman

AU - Zaccaria, Clara

AU - Pavesi, Lorenzo

PY - 2025/4/1

Y1 - 2025/4/1

N2 - In this study, we address the challenge of analyzing electrophysiological measurements in neuronal networks. Our computational model, based on the Reservoir Computing Network (RCN) architecture, deciphers spatio-temporal data obtained from electrophysiological measurements of neuronal cultures. By reconstructing the network structure on a macroscopic scale, we reveal the connectivity between neuronal units. Notably, our model outperforms common methods such as Cross-Correlation, Transfer-Entropy, and a recently developed related algorithm in predicting the network's connectivity map. Furthermore, we experimentally validate its ability to forecast network responses to specific inputs, including localized optogenetic stimuli.

AB - In this study, we address the challenge of analyzing electrophysiological measurements in neuronal networks. Our computational model, based on the Reservoir Computing Network (RCN) architecture, deciphers spatio-temporal data obtained from electrophysiological measurements of neuronal cultures. By reconstructing the network structure on a macroscopic scale, we reveal the connectivity between neuronal units. Notably, our model outperforms common methods such as Cross-Correlation, Transfer-Entropy, and a recently developed related algorithm in predicting the network's connectivity map. Furthermore, we experimentally validate its ability to forecast network responses to specific inputs, including localized optogenetic stimuli.

KW - Electrophysiological data

KW - Neural models

KW - Reservoir computing

UR - https://www.scopus.com/pages/publications/85213223932

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DO - 10.1016/j.neunet.2024.107058

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VL - 184

JO - Neural Networks

JF - Neural Networks

M1 - 107058

ER -

Decoding neuronal networks: A Reservoir Computing approach for predicting connectivity and functionality

Abstract

Keywords

ASJC Scopus subject areas

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