Capturing contextual effects in spectro-temporal receptive fields

Spectro-temporal receptive fields (STRFs) are thought to provide descriptive images of the computations performed by neurons along the auditory pathway. However, their validity can be questioned because they rely on a set of assumptions that are probably not fulfilled by real neurons exhibiting cont...

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Bibliographic Details
Published in:Hearing research 2016-09, Vol.339, p.195-210
Main Authors: Westö, Johan, May, Patrick J.C.
Format: Article
Language:English
Subjects:
Acoustic Stimulation
Action Potentials - physiology
Animals
Auditory
Auditory Cortex - physiology
Auditory Pathways
Auditory Perception - physiology
Computer Simulation
Context field
Contextual effects
Evoked Potentials, Auditory - physiology
Humans
Inhibition
Linear Models
Models, Neurological
Neuronal Plasticity
Neurons - physiology
Nonlinear Dynamics
Spectro-temporal receptive field
STRF
Synaptic depression
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Summary:Spectro-temporal receptive fields (STRFs) are thought to provide descriptive images of the computations performed by neurons along the auditory pathway. However, their validity can be questioned because they rely on a set of assumptions that are probably not fulfilled by real neurons exhibiting contextual effects, that is, nonlinear interactions in the time or frequency dimension that cannot be described with a linear filter. We used a novel approach to investigate how a variety of contextual effects, due to facilitating nonlinear interactions and synaptic depression, affect different STRF models, and if these effects can be captured with a context field (CF). Contextual effects were incorporated in simulated networks of spiking neurons, allowing one to define the true STRFs of the neurons. This, in turn, made it possible to evaluate the performance of each STRF model by comparing the estimations with the true STRFs. We found that currently used STRF models are particularly poor at estimating inhibitory regions. Specifically, contextual effects make estimated STRFs dependent on stimulus density in a contrasting fashion: inhibitory regions are underestimated at lower densities while artificial inhibitory regions emerge at higher densities. The CF was found to provide a solution to this dilemma, but only when it is used together with a generalized linear model. Our results therefore highlight the limitations of the traditional STRF approach and provide useful recipes for how different STRF models and stimuli can be used to arrive at reliable quantifications of neural computations in the presence of contextual effects. The results therefore push the purpose of STRF analysis from simply finding an optimal stimulus toward describing context-dependent computations of neurons along the auditory pathway. •Spectro-temporal receptive field (STRF) veracity was tested in simulated networks.•Stimulus density affects inhibitory regions in spectro-temporal receptive fields.•Lower densities render inhibitory regions invisible.•Higher densities give rise to artificial inhibitory regions.•Combining a context field with generalized linear models result in accurate STRFs.
ISSN:0378-5955
1878-5891
DOI:10.1016/j.heares.2016.07.012