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What is the neural code?

What is the neural code?. What is the neural code?. Alan Litke, UCSD. What is the neural code?. What is the neural code?. Encoding : how does a stimulus cause a pattern of responses? what are the responses and what are their characteristics? neural models:

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What is the neural code?

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  1. What is the neural code?

  2. What is the neural code? Alan Litke, UCSD

  3. What is the neural code?

  4. What is the neural code? • Encoding: how does a stimulus cause a pattern of responses? • what are the responses and what are their characteristics? • neural models: • what takes us from stimulus to response; • descriptive and mechanistic models, and the relation between them. • Decoding: what do these responses tell us about the stimulus? • Implies some kind of decoding algorithm • How to evaluate how good our algorithm is?

  5. What is the neural code? Single cells: spike rate spike times spike intervals

  6. What is the neural code? Single cells: spike rate: what does the firing rate correspond to? spike times: what in the stimulus triggers a spike? spike intervals: can patterns of spikes convey extra information?

  7. What is the neural code? Populations of cells: population coding correlations between responses synergy and redundancy

  8. Receptive fields and tuning curves Tuning curve: r = f(s) Gaussian tuning curve of a cortical (V1) neuron

  9. Receptive fields and tuning curves Tuning curve: r = f(s) Hand reaching direction Cosine tuning curve of a motor cortical neuron

  10. Receptive fields and tuning curves Retinal disparity for a “near” object Sigmoid/logistic tuning curve of a “stereo” V1 neuron

  11. Higher brain areas represent increasingly complex features Quian Quiroga, Reddy, Kreiman, Koch and Fried, Nature (2005)

  12. More generally, we are interested in determining the relationship: encoding P(response | stimulus) P(stimulus | response) decoding Due to noise, this is a stochastic description. Problem of dimensionality, both in response and in stimulus

  13. Reverse correlation Fast modulation of firing by dynamic stimuli Feature extraction Use reverse correlation to decide what each of these spiking events stands for, and so to either: -- predict the time-varying firing rate -- reconstruct the stimulus from the spikes

  14. Basic idea: throw random stimuli at the system and collect the ones that cause a response Reverse correlation Typically, use Gaussian, white noise stimulus: an unbiased stimulus which samples all directions equally S(t) r(t)

  15. Reverse correlation Spike-conditional ensemble Goal: simplify!

  16. Example: a neuron in the ELL of a fish stimulus = fluctuating potential (generates electric field) Spike-triggered Average

  17. This can be done with other dimensions of stimulus as well Spatio-temporal receptive field

  18. spike-triggering stimulus feature decision function Decompose the neural computation into a linear stage and a nonlinear stage. stimulus X(t) f1 spike output Y(t) x1 P(spike|x1 ) x1 To what feature in the stimulus is the system sensitive? Gerstner, spike response model; Aguera y Arcas et al. 2001, 2003; Keat et al., 2001 Modeling spike encoding Given a stimulus, when will the system spike? Simple example: the integrate-and-fire neuron

  19. spike-triggering stimulus feature decision function stimulus X(t) f1 spike output Y(t) x1 P(spike|x1 ) x1 Modeling spike encoding The decision function is P(spike|x1). Derive from data using Bayes’ theorem: P(spike|x1) = P(spike) P(x1 | spike) / P(x1) P(x1) is the prior : the distribution of all projections onto f1 P(x1 | spike) is the spike-conditional ensemble : the distribution of all projections onto f1 given there has been a spike P(spike) is proportional to the mean firing rate

  20. Models of neural function spike-triggering stimulus feature decision function stimulus X(t) f1 spike output Y(t) x1 P(spike|x1 ) x1 Weaknesses

  21. covariance Reverse correlation: a geometric view Gaussian prior stimulus distribution STA Spike-conditional distribution

  22. Cij = < S(t – ti) S(t - tj)> - < STA(t - ti) STA (t - tj)> - < I(t - ti) I(t - tj)> Dimensionality reduction The covariance matrix is given by Stimulus prior • Properties: • If the computation is low-dimensional, there will be a few eigenvalues • significantly different from zero • The number of eigenvalues is the relevant dimensionality • The corresponding eigenvectors span the subspace of the relevant features Bialek et al., 1997

  23. Functional models of neural function spike-triggering stimulus feature decision function stimulus X(t) f1 spike output Y(t) x1 P(spike|x1 ) x1

  24. Functional models of neural function spike-triggering stimulus features f1 multidimensional decision function x1 stimulus X(t) f2 spike output Y(t) x2 f3 x3

  25. Functional models of neural function ? ? ? spike-triggering stimulus features f1 x1 decision function stimulus X(t) f2 spike output Y(t) x2 f3 x3 spike history feedback

  26. Covariance analysis Let’s develop some intuition for how this works: the Keat model Keat, Reinagel, Reid and Meister, Predicting every spike. Neuron (2001) • Spiking is controlled by a single filter • Spikes happen generally on an upward threshold crossing of • the filtered stimulus •  expect 2 modes, the filter F(t) and its time derivative F’(t)

  27. Covariance analysis

  28. Covariance analysis Let’s try a real neuron: rat somatosensory cortex (Ras Petersen, Mathew Diamond, SISSA) Record from single units in barrel cortex

  29. Normalisedvelocity Pre-spike time (ms) Covariance analysis Spike-triggered average:

  30. Covariance analysis Is the neuron simply not very responsive to a white noise stimulus?

  31. Covariance analysis Prior Spike- triggered Difference

  32. 0.4 0.3 0.2 0.1 Velocity 0 -0.1 -0.2 -0.3 -0.4 150 100 50 0 Pre-spike time (ms) Covariance analysis Eigenspectrum Leading modes

  33. Covariance analysis Input/output relations wrt first two filters, alone: and in quadrature:

  34. 0.4 0.3 0.2 Velocity (arbitrary units) 0.1 0 -0.1 -0.2 -0.3 150 100 50 0 Pre-spike time (ms) Covariance analysis How about the other modes? Pair with -ve eigenvalues Next pair with +ve eigenvalues

  35. Covariance analysis Input/output relations for negative pair Firing rate decreases with increasing projection: suppressive modes

  36. Beyond covariance analysis • Single, best filter determined by the first moment • A family of filters derived using the second moment • Use the entire distribution: information theoretic methods  Find the dimensions that maximize the mutual information between stimulus and spike Removes requirement for Gaussian stimuli

  37. Limitations Not a completely “blind” procedure: have to have some idea of the appropriate stimulus space Very complex stimuli: does a geometrical picture work or make sense? Adaptation: stimulus representations change with experience!

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