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Srdjan Ostojic

ENS, Paris

January 22, 2025

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Structured Excitatory-Inhibitory Networks: a low-rank approach

Networks of excitatory and inhibitory (EI) neurons form a canonical circuit in the brain. Classical theoretical analyses of dynamics in EI networks have revealed key principles such as EI balance or paradoxical responses to external inputs. These seminal results assume that synaptic strengths depend on the type of neurons they connect but are otherwise statistically independent. However, recent synaptic physiology datasets have uncovered connectivity patterns that deviate significantly from independent connection models. Simultaneously, studies of task-trained recurrent networks have emphasized the role of connectivity structure in implementing neural computations. Despite these findings, integrating detailed connectivity structures into mean-field theories of EI networks remains a substantial challenge. In this talk, I will outline a theoretical approach to understanding dynamics in structured EI networks by employing a low-rank approximation based on an analytical computation of the dominant eigenvalues of the full connectivity matrix. I will illustrate this approach by investigating the effects of pair-wise connectivity motifs on linear dynamics in EI networks. Specifically, I will present recent results demonstrating that an over-representation of chain motifs induces a strong positive eigenvalue in inhibition-dominated networks, generating a potential instability that challenges classical EI balance criteria. Furthermore, by examining the effects of external input, we found that chain motifs can, on their own, induce paradoxical responses, wherein an increased input to inhibitory neurons leads to a counterintuitive decrease in their activity through recurrent feedback mechanisms. Altogether, our theoretical approach opens new avenues for relating recorded connectivity structures with dynamics and computations in biological networks.

A Geometric Approach for the Study of

Functional Connectivity Dynamics

Hadas Benisty

Technion

January 29, 2025

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Functional connectivity has been the focus of many research groups aiming to study the interaction between cells and brain regions. A standard method for analyzing connectivity is to statistically compare pairwise interactions between cells or brain regions across behavioral states or conditions. This methodology ignores the intrinsic properties of functional connectivity as a multivariate and dynamic signal, expressing the correlational configuration of the network. In this talk, I will present a geometric approach, combining Graph Theory and Riemannian Geometry to build "a graph of graphs" and extract the latent dynamics of the overall correlational structure. Using this approach, we formulate the statistical relations between network dynamics and spontaneous behavior as a second-order Taylor’s expansion. Our analysis shows that fast fluctuations in functional connectivity of large-scale cortical networks are closely linked to variations in behavioral metrics related to the arousal state. We further expand this methodology to longer time scales to study the effect of dopamine on network dynamics in the primary motor cortex (M1) during learning. We developed a series of analysis methods indicating that as animals learn to perform a motor task, the network of pyramidal neurons in layer 2-3 gradually and monotonically reorganizes toward an "expert" configuration. Our results highlight the critical role of dopamine in driving synaptic plasticity: Blocking dopaminergic neurotransmission locally in M1 prevented motor learning at the behavioral level and concomitantly halted plasticity changes in network activity and in functional connectivity.

Matthew Golub

University of Washington

February 5, 2025

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TBA

Lea Duncker

Stanford

February 12, 2025

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TBA

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Jens-Bastian Eppler

Goethe-Universität

Frankfurt am Main 

February 19, 2025

TBA

Songting Li

Jiao tong University

February 26, 2025

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TBA

Yonatan Loewenstein

ELSC, The Hebrew University

March 5, 2025

TBA

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Olivier Marre

Institut de la Vision, Paris

March 12, 2025

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TBA

Marcelo Rozenberg

Paris-Saclay University

March 19, 2025

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TBA

Eve of Cosyne

 

No Seminar 

March 26, 2025

The following day of Cosyne​

 

No Seminar 

April 2, 2025

James DiCarlo

MIT

April  9, 2025

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Carl van Vreeswijk Memorial Lecture

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TBA

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April 16, 2025

No Seminar

TBA

April 23, 2025

TBA

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April 30, 2025

No Seminar

Yohai Bar-Sinai

Tel Aviv University

May 7, 2025

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TBA

Tomoki Fukai

Okinawa Institute of Science and Technology

May 14, 2025

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TBA

Alexei Koulakov

Cold Spring Harbor Laboratory

May 21, 2025

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TBA

Nischal Mainali

May 28, 2025

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TBA

Bing Wen Brunton

University of Washington 

Seattle

June 4, 2025

TBA

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Ulises Pereira Oblinovic

Allen Institute

June 11, 2025

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TBA

Riccardo Zecchina

Bocconi University, Milano

June 18, 2025

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TBA

Andrew Barto

U. Mass

June 25, 2025

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VVTNS Fifth Season Closing Lecture

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