1 / 35

The Decisive Commanding Neural Network In the Parietal Cortex

The Decisive Commanding Neural Network In the Parietal Cortex. By Hsiu-Ming Chang ( 張修明 ). Shadlen & Newsom, 2001, J.Neurosci. Monkeys are trained to perform the motion discrimination task by eye saccades. For each neuron, a response field (RF) is determined.

jalila
Download Presentation

The Decisive Commanding Neural Network In the Parietal Cortex

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. The Decisive Commanding Neural Network In the Parietal Cortex By Hsiu-Ming Chang (張修明)

  2. Shadlen & Newsom, 2001, J.Neurosci.

  3. Monkeys are trained to perform the motion discrimination task by eye saccades. For each neuron, a response field (RF) is determined Shadlen & Newsom, 2001, J.Neurosci.

  4. Electrodes are inserted into the lateral intraparietal cortex Shadlen & Newsom, 2001, J.Neurosci.

  5. Single neurons favoring a specific direction of the eye movement are found Shadlen & Newsom, 2001, J.Neurosci.

  6. Activity elevated on a decision to move the eye to a specific direction Activity attenuated on a decision to move the eye away from a specific direction Shadlen & Newsom, 2001, J.Neurosci.

  7. The neural activity reaches the maximum just before the saccadic eye movement The neural activity follows the strength of the information Shadlen & Newsom, 2001, J.Neurosci.

  8. The reaction time is longer than the decay time of NMDA receptor activation The reaction with error decisions takes longer time than with the correct ones Roitman & Shadlen , 2002, J.Neurosci.

  9. The decision process is simulated in a theoretical network The resting potential VL, firing threshold Vth, and reset potential Vresetwere set respectively to −70mV, −50mV and −55mV. Else Wong & Wang, 2006, J. Neurosci

  10. where g was the peak synaptic conductance, S the synaptic gating variable (fraction of open channels), VE= 0 the reversal potential of excitatory connectivity, and VI= −70mV the reversal potential for inhibitory synapses. w was a dimensionless potentiation factor due to structured excitatory synapses The relatively strong synapses, a potentiation factor w = w+ = 1.7 is chosen1. A “depression” factor w = w− = 1−f(w+−1)/(1−f) < 1 for the synapses between two different selective populations, and for synapses between the nonselective population to selective ones. For all other connections, w = 1. Wong & Wang, 2006, J. Neurosci

  11. In units of μS, grec,AMPA= 0.0005, gext,AMPA= 0.0021, gNMDA= 0.000165, and grec,AMPA= 0.00004, gext,AMPA= 0.00162, gNMDA= 0.00013 to the interneurons. For inhibitory synapses to pyramidal cells and interneurons, gGABA, are 0.0013μS and 0.001μS respectively. Wong & Wang, 2006, J. Neurosci

  12. S is the synaptic gating variable ~ open probability The time constants were τAMPA = 2ms,τNMDA,decay = 100ms, τNMDA,rise = 2ms, τGABA = 5ms, andα = 0.5ms−1.The rise time for AMPA and GABA (< 1ms) were assumed to be instantaneous. Spikes from external of the network were assumed to go through AMPA receptors. Wong & Wang, 2006, J. Neurosci

  13. Approximations are made to simplify calculations For a total of 2000 neurons with 400 Inhibitory ones Wong & Wang, 2006, J. Neurosci

  14. F(yi)= Yi /(tNMDA(1-yi)), and yiis the steady state of Si. where i 1, 2, 3 denotes the two selective, and one nonselective excitatory populations, I is the inhibitory population. ri(t) is the instantaneous mean firing rate of the presynaptic excitatory population i, rI(t) is the mean firing rate of the inhibitory population. S and its associated are the average synaptic gating variable and its corresponding decay time constant, respectively. Wong & Wang, 2006, J. Neurosci

  15. the firing rate r of a leaky integrate-and-fire (LIF) neuron receiving noisy input r = Isyn is the total synaptic input to a single cell, and cE,Iis the gain factor. gE,Iis a noise factor that determines the shape of the “curvature” of . If gE,Iis large, would act like a linearthreshold function with IE,I/c as the threshold current. The values are, for pyramidal cells, IE = 125 Hz, gE = 0.16 s, and cE = 310(VnC)-1; and for interneurons, II =177Hz, gI = 0.087 s, and cI = 615(VnC)-1 Wong & Wang, 2006, J. Neurosci

  16. Assuming the interspike intervals to be nearly Poisson, the average gating variable can be fitted by a simple function where 0.641 and r is the presynaptic firing rate. Then F(y(r))=gr Wong & Wang, 2006, J. Neurosci

  17. Further reduction is achieved if approximations, r is time independent and NMDA receptors have a decay time constant much longer than others, are made. Under a wide range of conditions, the firing rate of the nonselective population changes only by a modest amount, assumed at a constant mean rate of 2 Hz. Applying linear approximation of the input– output transfer function of the inhibitory cell. where g2 = 2 and r0 = 11.5 Hz. Wong & Wang, 2006, J. Neurosci

  18. Assuming that all other variables achieve their steady states much faster than the NMDA gating variable SNMDA, which dominates the time evolution of the system. where i 1, 2 labels the two excitatory populations

  19. After approximations, only two equations are left for solving Wong & Wang, 2006, J. Neurosci

  20. the standard set of parameters for the two-variable model is as follows: JN,11 = 0.1561 nA = JN,22, JN,12 = 0.0264 nA = JN,21, JA,11 = 9.9026*10-4 nC = JA,22, JA,12 = 6.5177*10-5 nA Hz-1 = JA,21 and I0 = 0.2346 nA. Wong & Wang, 2006, J. Neurosci

  21. Input signal are applied to 15% of the total excitatory neurons where JA,ext = 0.2243 * 10-3 nA * Hz-1 is the average synaptic coupling with AMPARs and c’ is the degree of coherence where s2noise is the variance of the noise, and is a Gaussian white noise with zero mean and unit variance. Unless specified, noise is fixed at 0.007 nA. Wong & Wang, 2006, J. Neurosci

  22. A decision is made when the threshold the reached Wong & Wang, 2006, J. Neurosci

  23. The theoretical model reproduces the experimental results Stimulation Coherence Increases The accuracy Error takes Longer time To act Wong & Wang, 2006, J. Neurosci

  24. The coherence dependent responses are also demonstrated Wong & Wang, 2006, J. Neurosci

  25. Stronger stimulation results in shorter reaction time Wong & Wang, 2006, J. Neurosci

  26. Working memory Wong & Wang, 2006, J. Neurosci

  27. Wong & Wang, 2006, J. Neurosci

  28. Stimulation induces disturbance on the state of the network and creates transient unstable Wong & Wang, 2006, J. Neurosci

  29. Coherent stimulation separate two nullclines and reduce the number of attractors Wong & Wang, 2006, J. Neurosci

  30. Stronger recurrent current reduces the reaction time and accuracy Wong & Wang, 2006, J. Neurosci

  31. Increase the AMPA Component in the Recurrent current Results in shorter Reaction time but Less accuracy Wong & Wang, 2006, J. Neurosci

  32. Wong & Wang, 2006, J. Neurosci

  33. Decision Without Working Memory (instinct ?) Wong & Wang, 2006, J. Neurosci

  34. A logical elaboration of the decision making process In a neural system is demonstrated The functional significant neural activity is represented in a form of synchronization. Decision is made when the neural network reaches a steady state in activity

  35. The purpose for the vast number of neurons in the ensemble redundancy noise reduction (higher precision) The biological evidence of theoretical derivation of w is still ambiguous. The abrupt rise and drop of neural activity near the sccadic movement have not been simulated (interneuron factor ?)

More Related