AI Article Synopsis
- An interdisciplinary study links perceptual and neural responses in how our brain processes multiple senses together, particularly focusing on audiovisual interactions.
- The Minkowski formula, often used in psychophysics to describe sensory combination, aligns with findings that cortical bimodal neurons might be key to enhancing our sensory perception.
- In contrast, the superior colliculus processes audiovisual data differently, following a 'City-Block' rule, which highlights the complexity of how different brain regions handle sensory information.
Article Abstract
An interdisciplinary approach to sensory information combination shows a correspondence between perceptual and neural measures of nonlinear multisensory integration. In psychophysics, sensory information combinations are often characterized by the Minkowski formula, but the neural substrates of many psychophysical multisensory interactions are unknown. We show that audiovisual interactions - for both psychophysical detection threshold data and cortical bimodal neurons - obey similar vector-like Minkowski models, suggesting that cortical bimodal neurons could underlie multisensory perceptual sensitivity. An alternative Bayesian model is not a good predictor of cortical bimodal response. In contrast to cortex, audiovisual data from superior colliculus resembles the 'City-Block' combination rule used in perceptual similarity metrics. Previous work found a simple power law amplification rule is followed for perceptual appearance measures and by cortical subthreshold multisensory neurons. The two most studied neural cell classes in cortical multisensory interactions may provide neural substrates for two important perceptual modes: appearance-based and performance-based perception.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC8188495 | PMC |
| http://dx.doi.org/10.1016/j.isci.2021.102527 | DOI Listing |
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