Celotto, Marco and Bim, Jan and Tlaie, Alejandro and De Feo, Vito and Toso, Alessandro and Chicharro, Daniel and Lemke, Stefan M and Nili, Hamed and Bieler, Malte and Donner, Tobias H and Hanganu-Opatz, Ileana L and Brovelli, Andrea and Panzeri, Stefano (2023) An information-theoretic quantification of the content of communication between brain regions. In: 37th Conference on Neural Information Processing Systems (NeurIPS 2023), 2023-12-10 - 2023-12-16. (In Press)
Celotto, Marco and Bim, Jan and Tlaie, Alejandro and De Feo, Vito and Toso, Alessandro and Chicharro, Daniel and Lemke, Stefan M and Nili, Hamed and Bieler, Malte and Donner, Tobias H and Hanganu-Opatz, Ileana L and Brovelli, Andrea and Panzeri, Stefano (2023) An information-theoretic quantification of the content of communication between brain regions. In: 37th Conference on Neural Information Processing Systems (NeurIPS 2023), 2023-12-10 - 2023-12-16. (In Press)
Celotto, Marco and Bim, Jan and Tlaie, Alejandro and De Feo, Vito and Toso, Alessandro and Chicharro, Daniel and Lemke, Stefan M and Nili, Hamed and Bieler, Malte and Donner, Tobias H and Hanganu-Opatz, Ileana L and Brovelli, Andrea and Panzeri, Stefano (2023) An information-theoretic quantification of the content of communication between brain regions. In: 37th Conference on Neural Information Processing Systems (NeurIPS 2023), 2023-12-10 - 2023-12-16. (In Press)
Abstract
Quantifying the amount, content and direction of communication between brain regions is key to understanding brain function. Traditional methods to analyze brain activity based on the Wiener-Granger causality principle quantify the overall information propagated by neural activity between simultaneously recorded brain regions, but do not reveal the information flow about specific features of interest (such as sensory stimuli). Here, we develop a new information theoretic measure termed Feature-specific Information Transfer (FIT), quantifying how much information about a specific feature flows between two regions. FIT merges the Wiener-Granger causality principle with information-content specificity. We first derive FIT and prove analytically its key properties. We then illustrate and test them with simulations of neural activity, demonstrating that FIT identifies, within the total information flowing between regions, the information that is transmitted about specific features. We then analyze three neural datasets obtained with different recording methods, magneto- and electro-encephalography, and spiking activity, to demonstrate the ability of FIT to uncover the content and direction of information flow between brain regions beyond what can be discerned with traditional anaytical methods. FIT can improve our understanding of how brain regions communicate by uncovering previously hidden feature-specific information flow.
Item Type: | Conference or Workshop Item (Paper) |
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Additional Information: | Published proceedings: _not provided_ |
Divisions: | Faculty of Science and Health Faculty of Science and Health > Computer Science and Electronic Engineering, School of |
SWORD Depositor: | Unnamed user with email elements@essex.ac.uk |
Depositing User: | Unnamed user with email elements@essex.ac.uk |
Date Deposited: | 05 Jan 2024 11:55 |
Last Modified: | 05 May 2024 18:35 |
URI: | http://repository.essex.ac.uk/id/eprint/36505 |
Available files
Filename: FIT_camera_ready.pdf