Kanitscheider Ingmar, Coen-Cagli Ruben, Pouget Alexandre
Department of Basic Neuroscience, University of Geneva, 1211 Geneva, Switzerland; Center of Learning and Memory and Department of Neuroscience, The University of Texas at Austin, Austin, TX 78712;
Department of Basic Neuroscience, University of Geneva, 1211 Geneva, Switzerland;
Proc Natl Acad Sci U S A. 2015 Dec 15;112(50):E6973-82. doi: 10.1073/pnas.1508738112. Epub 2015 Nov 30.
The ability to discriminate between similar sensory stimuli relies on the amount of information encoded in sensory neuronal populations. Such information can be substantially reduced by correlated trial-to-trial variability. Noise correlations have been measured across a wide range of areas in the brain, but their origin is still far from clear. Here we show analytically and with simulations that optimal computation on inputs with limited information creates patterns of noise correlations that account for a broad range of experimental observations while at same time causing information to saturate in large neural populations. With the example of a network of V1 neurons extracting orientation from a noisy image, we illustrate to our knowledge the first generative model of noise correlations that is consistent both with neurophysiology and with behavioral thresholds, without invoking suboptimal encoding or decoding or internal sources of variability such as stochastic network dynamics or cortical state fluctuations. We further show that when information is limited at the input, both suboptimal connectivity and internal fluctuations could similarly reduce the asymptotic information, but they have qualitatively different effects on correlations leading to specific experimental predictions. Our study indicates that noise at the sensory periphery could have a major effect on cortical representations in widely studied discrimination tasks. It also provides an analytical framework to understand the functional relevance of different sources of experimentally measured correlations.
区分相似感觉刺激的能力依赖于感觉神经元群体中编码的信息量。这种信息会因逐次试验间的相关性变异性而大幅减少。噪声相关性已在大脑的广泛区域中被测量,但它们的起源仍远未明确。在这里,我们通过分析和模拟表明,对有限信息输入进行最优计算会产生噪声相关性模式,这些模式解释了广泛的实验观察结果,同时导致信息在大型神经群体中饱和。以从噪声图像中提取方向的V1神经元网络为例,据我们所知,我们阐述了第一个与神经生理学和行为阈值都一致的噪声相关性生成模型,而无需调用次优编码或解码或诸如随机网络动力学或皮层状态波动等内部变异性来源。我们进一步表明,当输入信息有限时,次优连接性和内部波动同样会降低渐近信息,但它们对相关性有质的不同影响,从而导致特定的实验预测。我们的研究表明,感觉外周的噪声可能对广泛研究的辨别任务中的皮层表征产生重大影响。它还提供了一个分析框架,以理解实验测量的相关性不同来源的功能相关性。