International audienceRetinal spike response to stimuli is constrained, on one hand by short range correlations (receptive field overlap) and on the other hand by lateral connectivity (cells connectivity). This last effect is difficult to handle fromstatistics because it requires to consider spatio-temporal correlations with a time delay long enough to take into account the time of propagation along synapses. Although MaxEnt model are useful to fit optimal model(maximizing entropy) under the constraints of reproducing observed correlations, they do address spatio-temporal correlations in their classical form (Ising or higher order interactions but without time delay). Binning insuch models somewhat integrates propagation effects, but in an implicit form, and increasing binning severely bias data [1]. To resolve this issue we have considered spatio-temporal MaxEnt model formerly developed e.g.by Vasquez et al. [2]. The price to pay, however is a huge set of parameters that must be fitted to experimental data to explain the observed spiking patterns statistics. There is no a priori knowledge of which parameters arerelevant and which ones are contributing to overfitting. We propose here a method of dimension reduction, i.e. a projection on a relevant subset of parameters, relying on the so-called Susceptibility matrix closely related tothe Fisher information. In contrast to standard methods in information geometry though, this matrix handle space and time correlations.We have applied this method for retina data obtained in a diurnal rodent (Octodon degus, having 30% of cones photoreceptors) and a 252-MEA system. Three types of stimuli were used: spatio-temporal uniform light, whitenoise and a natural movie. We show the role played by time-delayed pairwise interactions in the neural response to stimuli both for close and distant cells. Our conclusion is that, to explain the population spiking statisticswe need both short-distance interactions as well as long-distance interactions, meaning that the relevant functional correlations are mediated not only by common input (i.e. receptive field overlap, electrical coupling;spillover) but also by long range connections

Cessac, Bruno

Escobar, Maria-Jose

Herzog, Rubén

Palacios, Adrian

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Dimensionality Reduction in spatio-temporal MaxEnt models and analysis of Retinal Ganglion Cell Spiking Activity in experiments

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HAL Id: hal-01377370https://hal.archives-ouvertes.fr/hal-01377370Submitted on 8 Oct 2016HAL is a multi-disciplinary open accessarchive for the deposit and dissemination of sci-entific research documents, whether they are pub-lished or not. The documents may come fromteaching and research institutions in France orabroad, or from public or private research centers.L’archive ouverte pluridisciplinaire HAL, estdestinée au dépôt et à la diffusion de documentsscientifiques de niveau recherche, publiés ou non,émanant des établissements d’enseignement et derecherche français ou étrangers, des laboratoirespublics ou privés.Dimensionality Reduction in spatio-temporal MaxEntmodels and analysis of Retinal Ganglion Cell SpikingActivity in experimentsRubén Herzog, Maria-Jose Escobar, Adrian Palacios, Bruno CessacTo cite this version:Rubén Herzog, Maria-Jose Escobar, Adrian Palacios, Bruno Cessac. Dimensionality Reduction inspatio-temporal MaxEnt models and analysis of Retinal Ganglion Cell Spiking Activity in experiments.Bernstein Conference 2016 , Sep 2016, Berlin, Germany. ￿hal-01377370￿Dimensionality Reduction in spatio-temporal MaxEntmodels and analysis of Retinal Ganglion CellSpiking Activity in experimentsRuben Herzog1, Maria-Jose Escobar2, Adrian Palacios1, Bruno Cessac31 Centro Interdisciplinario de Neurociencia de Valparaiso, Universidad de Valparaiso. 2 Departamento de Electronica, Universidad TecnicaFederico Santa Maria. 3 INRIA Biovision team Sophia Antipolis and Universite Cote d’Azur.rubenherzog@ug.uchile.clINTRODUCTIONRetinal spike response to stimuli is constrained, on one hand by short range correlations (receptive field overlap) and on the other hand by lateral connectivity (cells connectivity). This last effect is difficult to handle fromstatistics because it requires to consider spatio-temporal correlations with a time delay long enough to take into account the time of propagation along synapses. Although MaxEnt model are useful to fit optimal model(maximizing entropy) under the constraints of reproducing observed correlations, they do address spatio-temporal correlations in their classical form (Ising or higher order interactions but without time delay). Binning insuch models somewhat integrates propagation effects, but in an implicit form, and increasing binning severely bias data [1]. To resolve this issue we have considered spatio-temporal MaxEnt model formerly developed e.g.by Vasquez et al. [2]. The price to pay, however is a huge set of parameters that must be fitted to experimental data to explain the observed spiking patterns statistics. There is no a priori knowledge of which parameters arerelevant and which ones are contributing to overfitting. We propose here a method of dimension reduction, i.e. a projection on a relevant subset of parameters, relying on the so-called Susceptibility matrix closely related tothe Fisher information. In contrast to standard methods in information geometry though, this matrix handle space and time correlations.We have applied this method for retina data obtained in a diurnal rodent (Octodon degus, having 30% of cones photoreceptors) and a 252-MEA system. Three types of stimuli were used: spatio-temporal uniform light, whitenoise and a natural movie. We show the role played by time-delayed pairwise interactions in the neural response to stimuli both for close and distant cells. Our conclusion is that, to explain the population spiking statisticswe need both short-distance interactions as well as long-distance interactions, meaning that the relevant functional correlations are mediated not only by common input (i.e. receptive field overlap, electrical coupling;spillover) but also by long range connections.χ SPECTRAL PROPERTIES UNDER DIFFERENT STIMULI(a) The χ eigenvalue spectrum obtained for PSA, WN and NM stimuli.The graphs shows two cut-offs: The first cut-off, close to the networksizeN represented as a vertical dashed line, is mainly to the effect of in-dividual firing rates. The second cut-off is associated to the informationcontained on spatio-temporal pairwise interactions. Minimizing eq. (3),we obtain different values of kc which are represented as squares oneach curve.(b) Volume V(k, ε) obtained for PSA, WN and NM stimuli. In the threecases, kc minimizing V(k, ε) is represented with a square. The num-ber of relevant dimensions kc, exceeds the firing rates meaning thatspatio-temporal pairwise interactions are needed for the optimal valueof V(k, ε).Remark: The number of optimal dimensions kc required to fit the empirical distribution increases with the stimuli high-order correlations.METHODSRecordings: Extracellular recording of the electrical activity of reti-nal patches from 4 healthy, young individuals of the rodent speciesOctodon degus were performed ex vivo using a Multielectrode Array(USB-MEA256 from Multichannel Systems, MCS GmbH).Stimuli: (i) Photopic spontaneous activity (PSA): A uniform spatio-temporal invariant full field (15 mins); (ii) White noise (WN): Bi-nary checkerboard pattern (20 mins); and, (iii) Natural Movie (NM):recorded in the animal’s natural environment (30s movie, 40 repeti-tions).PSA WN NMThe images were projected using a conventional DLP LED projectorat 60fps and registered at 20KHz. Sorting was done using OfflineSorter R©by Plexon Inc, and the spatio-temporal receptive fields werecomputed using STA in WN stimulus.Analysis: A binary raster ω ofN = 50 neurons with a bin size of 5mswere used, where ωn(t) = 1 if neuron n spikes at time t, 0 otherwise.The goal is to fit the empirical distribution of ω with a MaxEnt model(eq. 1) and compute its corresponding Susceptibility matrix χ (eq. 2):H(ω) =∑Ll=0 hlml(ω) (1), χll′ =∂µ[ml ]∂hl′(2)where mls are the observables, hl the free parameters to fit, l is pa-rameter label. t ranges from 0 to R − 1, where the integer R ≥ 1 iscalled the range (i.e. memory) of the potentialH, in this case,R = 2.The Susceptibility matrix (eq. 2) tells us how much a slight change onone parameter (hl) changes the estimation of the observables probabil-ities (ml). χ depends on stimuli, increasing their entries as the stimulicomplexity increases.DIMRED: GEOMETRIC INTUITIONThe set of indistinguishable distributions around the optimal set ofparameters defines an ellipsoid on the parameter space (see a) with avolume V satisfying:logV(k) =12SH(k)− log Γ(k2+ 1)+k2log(2πεT), (3)SH(k) = −k∑i=1log λi (4)where λis are decreasing χ eigenvalues; log Γ( k2 + 1) is purely com-binatoric; log(2πεT)characterizes the effect of precision accuracy (ε)and finite sampling. Minimizing eq. (1) is yields the optimal set ofparameters given a finite sample size (T ) with accuracy ε.(a) illustrates model composed by the Rates of two neurons (Rate Dim.1 and 2) and the spatio-temporal correlations between both (z axis).The ellipsoid is more elongated on the sloppy eigendirections (corre-lations) and less elongated on the stiff eigendirections (rates).(b) shows the value of the volume, V(k, ε) as the degrees of freedom(k) increases. The volume reaches a minimum (dots) for certain knamed as kc. Increasing k upon kc makes the volume explode.FROM χ TO NETWORK PROPERTIESThe effect on the estimation of slight changes in the lth parameter is computed as∑k=Kk=1 λkv2lk , where vlk is the lth entry of the eigenvector ~vkand λk is corresponding eigenvalue. The Change Index (C.I. equation on a) is the ratio of the effect before (K = L) and after filtering (K = kc).C.I.=1 means no filtering effect and C.I.=0 means full filtering effect. C.I. summarizes the effect of filtering on the direct influence of hl on mlestimation and all the indirect influences (hl acts onm′l which modifiesml)(a) shows the distribution of C.I. values for the pairwise parameters, where PSA shows two modes, one close to 0 and other to 1. WN and NMshows one big mode close to 1. Thus, static stimulus (PSA) shows much more pairwise parameters affected by filtering than dynamic ones.(b) shows the % of the remaining pairwise spatial (solid) and temporal (dashed) parameters as the C.I. threshold increases. Temporal interactionsare more abundant than spatial ones for all stimuli at all thresholds. PSA shows less remaining pairwise parameters than dynamic stimuli forall thresholds. Then, the number of spatio-temporal parameters required to optimally fit the empirical distribution increases with the stimulihigh-order correlations.(c) shows the Receptive Field (RF) Spacing (< 1 overlap; = 1 adjacency, horizontal dashed line; > 1 no overlap) as the C.I. threshold increasesfor spatial (blue) and temporal (black) parameters. Lines are medians and shaded area the interquartile range. We see the same behaviour for allcases: the RF spacing slightly decreases with C.I. threshold, showing that the optimal set of parameter includes both short-range (i.e. RF overlap)and long-range (no overlap) pairwise interactions for all stimuli.SYNTHETIC DATA: FIRING RATES ON N FIRST DIMENSIONS, CORRELATIONS ON FIRST kcThree synthetic rasters (T = 106, N = 10) were generated using 3 different underlying statistics: (i) Independent, with firing rates, L = N ;(ii) Ising, firing rates and spatial correlations, L = N(N − 1)/2; (iii) Pairwise R=2 (PWR2), with firing rates and spatio-temporal correlations,L = N(N − 1)/2 + N2. For each raster a PWR2 MaxEnt model was fit. The respective χ matrices were filtered with kc = 10, 15 and 127,respectively (see eq. 1 and 2). Then, the C.I. was computed for each parameter in order to link relevant dimensions with relevant parameters.(a) By construction the Indep. raster shows no pairwise parameters at thresholds as small as 0.03, while Ising raster, at the same threshold,shows only firing rate and spatial correlations parameters. PWR2 shows a small reduction on the % of remaining spatio-temporal parameters forkc = 127 but keeping most of them, whereas using kc = N removes all the pairwise parameters at very low thresholds.(b) The monomials probabilities show a non-linear relationship with C.I.. Monomials with low probabilities are likely to show low C.I. values.The Indep. raster shows only firing rates parameters with C.I.∼ 1; Ising raster shows firing rates and spatial correlations parameters with C.I.∼1, but none related to temporal correlations shows high C.I.; Almost all PWR2 parameters show C.I.∼ 1 when filtering with kc, but filtering withkc = N , reduces the C.I. of most of the spatio-temporal parameters at values∼ 0.2, while most firing rates parameters remain unchanged.The first N dimensions contains mainly information about firing rates, while the next kc − N concentrates information about spatio-temporalcorrelations.CONCLUSIONS(i) The first cut-off of χ spectrum contains mainly information about individual neuron firing rates, while the second cut-off contains informationabout spatio-temporal correlations. If kc = N , there is no relevant information about spatio-temporal correlations on the data and it can beoptimally explained by a model which takes into account only neuron firing rates.(ii) All tested stimuli requires spatio-temporal interactions to optimally fit the evoked retinal population activity. So, as other works have shownon different species (salamander [2,3,5]; monkey [4]; guinea pig[3]), retinal population activity presents significant spatio-temporal interactions.Moreover, the stimuli high-order correlations increases the number of relevant spatio-temporal interactions on the network.(iii) The optimal set of pairwise parameters, which implies a pair of neurons, includes neurons with overlapped receptive fields as well as distant neurons for alltested stimuli, with small differences between stimuli. Short range correlations can be explained via stimulus correlation and receptive field overlap whether longrange more presumably reflect lateral connectivity effects.ACKNOWLEDGEMENTSThis work has been supported by CONICYT-Fondecyt 1140403 and 1150638, CONICYT-BasalProject FB0008, Millennium Institute ICM-P09-022-F, ECOS-Conicyt C13E06. Special thanks to Dr.Patricio Orio for the access to the computational cluster of the CNSLab at the CINV.ENAS software (https://enas.inria.fr/) was used for the computation ofχ.REFERENCES[1] B. Cessac, A. Le Ny, Eva LÃűcherbach. Neural Computation, (In press), (2016).[2] J.C. Vasquez, A. Palacios, O. Marre, M.J. Berry II, B. Cessac, Gibbs distribution analysis of tem-poral correlation structure on multicell spike trains from retina ganglion cells, J. Physiol. Paris,Volume 106, Issues 3-4.[3] Schneidman, E., Berry, M. J., Segev, R., Bialek, W. (2006). Weak pairwise correlations implystrongly correlated network states in a neural population. Nature, 440(7087), 1007-12.[4] Shlens, J., Field, G. D., Gauthier, J. L., Grivich, M. I., Petrusca, D., Sher, A., Chichilnisky, E. J.(2006). The structure of multi-neuron firing patterns in primate retina. The Journal of Neuroscience: The Official Journal of the Society for Neuroscience, 26(32), 8254-66.[5] Tkacik, G., Marre, O., Amodei, D., Schneidman, E., Bialek, W., Berry, M. J. (2014). Searchingfor collective behavior in a large network of sensory neurons. PLoS Computational Biology, 10(1),e1003408.

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Dimensionality Reduction in spatio-temporal MaxEnt models and analysis of Retinal Ganglion Cell Spiking Activity in experiments

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