Pietro Berkes scite author profile

The brain maintains internal models of its environment to interpret sensory inputs and prepare actions. While behavioral studies demonstrated that these internal models are optimally adapted to the statistics of the environment, the neural underpinning of this adaptation is unknown. Using a Bayesian model of sensory cortical processing, we related stimulus-evoked and spontaneous activities to inferences and prior expectations in an internal model and predicted that they should match if the model is statistically optimal. To test this prediction, we analyzed visual cortical activity of awake ferrets during development. Similarity between spontaneous and evoked activities increased with age and was specific to responses evoked by natural scenes. This demonstrates the progressive adaptation of internal models to the statistics of natural stimuli at the neural level.

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Statistically optimal perception and learning: from behavior to neural representations

Fiser

Berkes

Orbán

et al. 2010

Trends in Cognitive Sciences

616

675

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Human perception has recently been characterized as statistical inference based on noisy and ambiguous sensory inputs. Moreover, suitable neural representations of uncertainty have been identified that could underlie such probabilistic computations. In this review, we argue that learning an internal model of the sensory environment is another key aspect of the same statistical inference procedure and thus perception and learning need to be treated jointly. We review evidence for statistically optimal learning in humans and animals, and reevaluate possible neural representations of uncertainty based on their potential to support statistically optimal learning. We propose that spontaneous activity can have a functional role in such representations leading to a new, samplingbased, framework of how the cortex represents information and uncertainty. Probabilistic perception, learning and representation of uncertainty: in need of a unifying approachOne of the longstanding computational principles in neuroscience is that the nervous system of animals and humans is adapted to the statistical properties of the environment [1]. This principle is reflected across all organizational levels, ranging from the activity of single neurons to networks and behavior, and it has been identified as key to the survival of organisms [2]. Such adaptation takes place on at least two distinct behaviorally relevant time scales: on the time scale of immediate inferences, as a moment-by-moment processing of sensory input (perception), and on a longer time scale by learning from experience. Although statistically optimal perception and learning have most often been considered in isolation, here we promote them as two facets of the same underlying principle and treat them together under a unified approach.Although there is considerable behavioral evidence that humans and animals represent, infer and learn about the statistical properties of their environment efficiently [3], and there is also NIH-PA Author ManuscriptNIH-PA Author Manuscript NIH-PA Author Manuscript converging theoretical and neurophysiological work on potential neural mechanisms of statistically optimal perception [4], there is a notable lack of convergence from physiological and theoretical studies explaining whether and how statistically optimal learning might occur in the brain. Moreover, there is a missing link between perception and learning: there exists virtually no crosstalk between these two lines of research focusing on common principles and on a unified framework down to the level of neural implementation. With recent advances in understanding the bases of probabilistic coding and the accumulating evidence supporting probabilistic computations in the cortex, it is now possible to take a closer look at both the basis of probabilistic learning and its relation to probabilistic perception.We first provide a brief overview of the theoretical framework as well as behavioral and neural evidence for representing uncertainty in perceptual processes. To highlight th...

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Neural Variability and Sampling-Based Probabilistic Representations in the Visual Cortex

Orbán

Berkes

Fiser

et al. 2016

Neuron

249

340

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SummaryNeural responses in the visual cortex are variable, and there is now an abundance of data characterizing how the magnitude and structure of this variability depends on the stimulus. Current theories of cortical computation fail to account for these data; they either ignore variability altogether or only model its unstructured Poisson-like aspects. We develop a theory in which the cortex performs probabilistic inference such that population activity patterns represent statistical samples from the inferred probability distribution. Our main prediction is that perceptual uncertainty is directly encoded by the variability, rather than the average, of cortical responses. Through direct comparisons to previously published data as well as original data analyses, we show that a sampling-based probabilistic representation accounts for the structure of noise, signal, and spontaneous response variability and correlations in the primary visual cortex. These results suggest a novel role for neural variability in cortical dynamics and computations.

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Slow feature analysis yields a rich repertoire of complex cell properties

2005

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In this study we investigate temporal slowness as a learning principle for receptive fields using slow feature analysis, a new algorithm to determine functions that extract slowly varying signals from the input data. We find a good qualitative and quantitative match between the set of learned functions trained on image sequences and the population of complex cells in the primary visual cortex (V1). The functions show many properties found also experimentally in complex cells, such as direction selectivity, non-orthogonal inhibition, end-inhibition, and side-inhibition. Our results demonstrate that a single unsupervised learning principle can account for such a rich repertoire of receptive field properties.

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Perceptual Decision-Making as Probabilistic Inference by Neural Sampling

Haefner

Berkes

Fiser³

2016

Neuron

206

262

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We address two main challenges facing systems neuroscience today: understanding the nature and function of cortical feedback between sensory areas and of correlated variability. Starting from the old idea of perception as probabilistic inference, we show how to use knowledge of the psychophysical task to make testable predictions for the influence of feedback signals on early sensory representations. Applying our framework to a two-alternative forced choice task paradigm, we can explain multiple empirical findings that have been hard to account for by the traditional feedforward model of sensory processing, including the task dependence of neural response correlations and the diverging time courses of choice probabilities and psychophysical kernels. Our model makes new predictions and characterizes a component of correlated variability that represents task-related information rather than performance-degrading noise. It demonstrates a normative way to integrate sensory and cognitive components into physiologically testable models of perceptual decision-making.

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Pietro Berkes

Spontaneous Cortical Activity Reveals Hallmarks of an Optimal Internal Model of the Environment

Statistically optimal perception and learning: from behavior to neural representations

Neural Variability and Sampling-Based Probabilistic Representations in the Visual Cortex

Slow feature analysis yields a rich repertoire of complex cell properties

Perceptual Decision-Making as Probabilistic Inference by Neural Sampling

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