Time-warp-invariant neuronal processing

Fluctuations in the temporal durations of sensory signals constitute a major source of variability within natural stimulus ensembles. The neuronal mechanisms through which sensory systems can stabilize perception against such fluctuations are largely unknown. An intriguing instantiation of such robu...

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Bibliographic Details
Published in:PLoS biology 2009-07, Vol.7 (7), p.e1000141-e1000141
Main Authors: Gütig, Robert, Sompolinsky, Haim
Format: Article
Language:English
Subjects:
Acoustic Stimulation
Analysis
Auditory Pathways - physiology
Computational Biology/Computational Neuroscience
Female
Human performance
Humans
Invariant subspaces
Learning - physiology
Male
Mental Processes - physiology
Neural circuitry
Neural Conduction - physiology
Neural Networks (Computer)
Neuronal Plasticity - physiology
Neurons - physiology
Neuroscience/Neuronal Signaling Mechanisms
Neuroscience/Sensory Systems
Neuroscience/Theoretical Neuroscience
Physiological aspects
Reaction Time - physiology
Sound Spectrography
Speech
Speech perception
Speech Perception - physiology
Studies
Synaptic Transmission - physiology
Temporal integration
Time
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Summary:Fluctuations in the temporal durations of sensory signals constitute a major source of variability within natural stimulus ensembles. The neuronal mechanisms through which sensory systems can stabilize perception against such fluctuations are largely unknown. An intriguing instantiation of such robustness occurs in human speech perception, which relies critically on temporal acoustic cues that are embedded in signals with highly variable duration. Across different instances of natural speech, auditory cues can undergo temporal warping that ranges from 2-fold compression to 2-fold dilation without significant perceptual impairment. Here, we report that time-warp-invariant neuronal processing can be subserved by the shunting action of synaptic conductances that automatically rescales the effective integration time of postsynaptic neurons. We propose a novel spike-based learning rule for synaptic conductances that adjusts the degree of synaptic shunting to the temporal processing requirements of a given task. Applying this general biophysical mechanism to the example of speech processing, we propose a neuronal network model for time-warp-invariant word discrimination and demonstrate its excellent performance on a standard benchmark speech-recognition task. Our results demonstrate the important functional role of synaptic conductances in spike-based neuronal information processing and learning. The biophysics of temporal integration at neuronal membranes can endow sensory pathways with powerful time-warp-invariant computational capabilities.
ISSN:1545-7885
1544-9173
1545-7885
DOI:10.1371/journal.pbio.1000141