Literature DB >> 18977448

Neural mechanisms for illusory filling-in of degraded speech.

Antoine J Shahin1, Christopher W Bishop, Lee M Miller.   

Abstract

The brain uses context and prior knowledge to repair degraded sensory inputs and improve perception. For example, listeners hear speech continuing uninterrupted through brief noises, even if the speech signal is artificially removed from the noisy epochs. In a functional MRI study, we show that this temporal filling-in process is based on two dissociable neural mechanisms: the subjective experience of illusory continuity, and the sensory repair mechanisms that support it. Areas mediating illusory continuity include the left posterior angular gyrus (AG) and superior temporal sulcus (STS) and the right STS. Unconscious sensory repair occurs in Broca's area, bilateral anterior insula, and pre-supplementary motor area. The left AG/STS and all the repair regions show evidence for word-level template matching and communicate more when fewer acoustic cues are available. These results support a two-path process where the brain creates coherent perceptual objects by applying prior knowledge and filling-in corrupted sensory information.

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Year:  2008        PMID: 18977448      PMCID: PMC2653101          DOI: 10.1016/j.neuroimage.2008.09.045

Source DB:  PubMed          Journal:  Neuroimage        ISSN: 1053-8119            Impact factor:   6.556


  52 in total

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8.  Use of speech-modulated noise adds strong "bottom-up" cues for phonemic restoration.

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  43 in total

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Review 5.  Evolutionary conservation and neuronal mechanisms of auditory perceptual restoration.

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6.  The phonemic restoration effect reveals pre-N400 effect of supportive sentence context in speech perception.

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7.  Aberrant connectivity of areas for decoding degraded speech in patients with auditory verbal hallucinations.

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8.  Multisensory integration enhances phonemic restoration.

Authors:  Antoine J Shahin; Lee M Miller
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9.  Perceptual asymmetry induced by the auditory continuity illusion.

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10.  Children use visual speech to compensate for non-intact auditory speech.

Authors:  Susan Jerger; Markus F Damian; Nancy Tye-Murray; Hervé Abdi
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