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Biological Modeling of Neural Networks: Week 15 – Fast Transients and Rate models Wulfram Gerstner EPFL, Lausanne, Switzerland 15.1 Review Populations.

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Presentation on theme: "Biological Modeling of Neural Networks: Week 15 – Fast Transients and Rate models Wulfram Gerstner EPFL, Lausanne, Switzerland 15.1 Review Populations."— Presentation transcript:

1 Biological Modeling of Neural Networks: Week 15 – Fast Transients and Rate models Wulfram Gerstner EPFL, Lausanne, Switzerland 15.1 Review Populations of Neurons - Transients 15.2 Rate models - Week 15 – transients and rate models

2 Neuronal Dynamics – Brain dynamics is complex motor cortex frontal cortex to motor output 10 000 neurons 3 km of wire 1mm Week 15-part 1: Review: The brain is complex

3 Homogeneous population: -each neuron receives input from k neurons in the population -each neuron receives the same (mean) external input (could come from other populations) -each neuron in the population has roughly the same parameters Week 15-part 1: Review: Homogeneous Population excitation inhibition Example: 2 populations

4 I(t) Week 15-part 1: Review: microscopic vs. macroscopic microscopic: -spikes are generated by individual neurons -spikes are transmitted from neuron to neuron macroscopic: -Population activity A n (t) -Populations interact via A n (t)

5 I(t) Week 15-part 1: Review: coupled populations

6 Populations: - pyramidal neurons in layer 5 of barrel D1 - pyramidal neurons in layer 2/3 of barrel D1 - inhibitory neurons in layer 2/3 of barrel D1 Week 15-part 1: Example: coupled populations in barrel cortex Neuronal Populations = a homogeneous group of neurons (more or less) 100-2000 neurons per group (Lefort et al., NEURON, 2009) different barrels and layers, different neuron types  different populations

7 Experimental data : Marsalek et al., 1997 Week 15-part 1: A(t) in experiments:light flash, in vivo PSTH, single neurons aligned PSTH, many neurons in V1 (solid) V4 (dashed)

8 Experimental data : Sakata and Harris, 2009 Week 15-part 2: A(t) in experiments: auditory click stimulus

9 Experimental data : Tchumatchenko et al. 2011 See also: Poliakov et al. 1997 Week 15-part 1: A(t) in experiments: step current, (in vitro)

10 Week 15-part 1: A(t) in simulations of integrate-and-fire neurons Simulation data : Brunel et al. 2011 Image: Gerstner et al., Neuronal Dynamics, 2014

11 Week 15-part 1: A(t) in simulations of integrate-and-fire neurons Simulation data : Image: Gerstner et al., Neuronal Dynamics, 2014

12 Biological Modeling of Neural Networks: Week 15 – Fast Transients and Rate models Wulfram Gerstner EPFL, Lausanne, Switzerland Week 15 – transients and rate models Transients are very fast -In experiments -In simulations of spiking neurons Conclusion of part 1

13 h(t) Input potential Week 15-part 2: Rate model with differential equation I(t)  Differential equation can be integrated!, exponential kernel

14 A(t) h(t) Input potential Week 15-part 2: Rate model : step current I(t) Example LNP rate model: Linear-Nonlinear-Poisson Spikes are generated by a Poisson process, from rate model

15 A(t) h(t) Input potential Week 15-part 2: Wilson-Cowan model : step current I(t)

16 Population of Neurons? Single neurons - model exists - parameters extracted from data - works well for step current - works well for time-dep. current Population equation for A(t) Week 15-part 2: Aim: from single neuron to population -existing models - integral equation

17 25000 identical model neurons (GLM/SRM with escape noise) parameters extracted from experimental data response to step current I(t) h(t) Input potential simulation data : Naud and Gerstner, 2012 Week 15-part 2: A(t) in simulations : step current

18 I(t) Rate adapt. optimal filter (rate adaptation) Benda-Herz Week 15-part 2: rate model LNP theory simulation Simple rate model: - too slow during the transient - no adaptation

19 I(t) Rate adapt. optimal filter (rate adaptation) Benda-Herz Week 15-part : rate model with adaptation simulation LNP theory

20 Rate adapt. optimal filter (rate adaptation) Benda-Herz Week 15-part 2: rate model Simple rate model: - too slow during the transient - no adaptation Adaptive rate model: - too slow during the transient - final adaptation phase correct Rate models can get the slow dynamics and stationary state correct, but are wrong during transient

21 h(t) I(t) ? A(t) potential A(t) t population activity Question: – what is correct? Poll!!! A(t) Wilson-Cowan Benda-Herz LNP current Ostojic-Brunel Paninski, Pillow Week 15-part 2: population equation for A(t) ?

22 optimal filter (rate adaptation) Week 15-part 2: improved rate models/population models Improved rate models a) rate model with effective time constant  next slides b) integral equation approach  chapter 14

23 h(t) Input potential Week 15-part 2: Rate model with effective time constant I(t)  Ostojic-Brunel, 2011  Shorter effective time constant during high activity

24 Week 15-part 2: Rate model with effective time constant Ostojic-Brunel, 2011  Shorter effective time constant during high activity  Theory fits simulation very well Image: Gerstner et al., Neuronal Dynamics, CUP 2014

25 optimal filter (rate adaptation) Week 15-part 2; Conclusions Rate models - are useful, because they are simple - slow dynamics and stationary state correct - simple rate models have wrong transients - improved rate models/population activity models exist

26 The end Reading: Chapter 15 of NEURONAL DYNAMICS, Gerstner et al., Cambridge Univ. Press (2014)

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