Zylberberg Joel, Pouget Alexandre, Latham Peter E, Shea-Brown Eric
Department of Physiology and Biophysics, Center for Neuroscience, and Computational Bioscience Program, University of Colorado School of Medicine, Aurora, Colorado, United States of America.
Department of Applied Mathematics, University of Colorado, Boulder, Colorado, United States of America.
PLoS Comput Biol. 2017 Apr 18;13(4):e1005497. doi: 10.1371/journal.pcbi.1005497. eCollection 2017 Apr.
Sensory neurons give highly variable responses to stimulation, which can limit the amount of stimulus information available to downstream circuits. Much work has investigated the factors that affect the amount of information encoded in these population responses, leading to insights about the role of covariability among neurons, tuning curve shape, etc. However, the informativeness of neural responses is not the only relevant feature of population codes; of potentially equal importance is how robustly that information propagates to downstream structures. For instance, to quantify the retina's performance, one must consider not only the informativeness of the optic nerve responses, but also the amount of information that survives the spike-generating nonlinearity and noise corruption in the next stage of processing, the lateral geniculate nucleus. Our study identifies the set of covariance structures for the upstream cells that optimize the ability of information to propagate through noisy, nonlinear circuits. Within this optimal family are covariances with "differential correlations", which are known to reduce the information encoded in neural population activities. Thus, covariance structures that maximize information in neural population codes, and those that maximize the ability of this information to propagate, can be very different. Moreover, redundancy is neither necessary nor sufficient to make population codes robust against corruption by noise: redundant codes can be very fragile, and synergistic codes can-in some cases-optimize robustness against noise.
感觉神经元对刺激的反应高度可变,这可能会限制下游神经回路可获得的刺激信息量。许多研究致力于探究影响这些群体反应中编码信息量的因素,从而深入了解神经元间协变性、调谐曲线形状等的作用。然而,神经反应的信息性并非群体编码唯一相关的特征;同样重要的是该信息传递到下游结构的稳健程度。例如,为了量化视网膜的性能,不仅必须考虑视神经反应的信息性,还需考虑在下一处理阶段(外侧膝状体)中,在产生动作电位的非线性和噪声干扰后仍能保留的信息量。我们的研究确定了上游细胞的协方差结构集,这些结构可优化信息通过有噪声的非线性神经回路进行传递的能力。在这个最优集合中存在具有“差异相关性”的协方差,已知这种协方差会减少神经群体活动中编码的信息。因此,使神经群体编码中的信息最大化的协方差结构,与使该信息传递能力最大化的协方差结构可能会有很大差异。此外,冗余对于使群体编码抵御噪声干扰既非必要条件也非充分条件:冗余编码可能非常脆弱,而协同编码在某些情况下可优化对噪声的稳健性。
