Entire Sound Representations Are Time-Compressed in Sensory Memory: Evidence from MMN

Seiji Tamakoshi,Nanako Minoura,Akihiro Yagi,Jun'Ichi Katayama

doi:10.3389/fnins.2016.00347

Seiji Tamakoshi, Nanako Minoura + Show 2 more

Open Access

https://doi.org/10.3389/fnins.2016.00347

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Abstract

In order to examine the encoding of partial silence included in a sound stimulus in neural representation, time flow of the sound representations was investigated using mismatch negativity (MMN), an ERP component that reflects neural representation in auditory sensory memory. Previous work suggested that time flow of auditory stimuli is compressed in neural representations. The stimuli used were a full-stimulus of 170 ms duration, an early-gap stimulus with silence for a 20–50 ms segment (i.e., an omitted segment), and a late-gap stimulus with an omitted segment of 110–140 ms. Peak MMNm latencies from oddball sequences of these stimuli, with a 500 ms SOA, did not reflect time point of the physical gap, suggesting that temporal information can be compressed in sensory memory. However, it was not clear whether the whole stimulus duration or only the omitted segment duration is compressed. Thus, stimuli were used in which the gap was replaced by a tone segment with a 1/4 sound pressure level (filled), as well as the gap stimuli. Combinations of full-stimuli and one of four gapped or filled stimuli (i.e., early gap, late gap, early filled, and late filled) were presented in an oddball sequence (85 vs. 15%). If compression occurs only for the gap duration, MMN latency for filled stimuli should show a different pattern from those for gap stimuli. MMN latencies for the filled conditions showed the same pattern as those for the gap conditions, indicating that the whole stimulus duration rather than only gap duration is compressed in sensory memory neural representation. These results suggest that temporal aspects of silence are encoded in the same manner as physical sound.

Highlights

In order to process continuously changing auditory information over the course of everyday life, the human brain integrates auditory information as a unitary event about every 200 ms. This auditory integration duration is called a temporal window of integration (TWI), and it is used to integrate processes as a “sliding window” in the sound representation (Näätänen, 1990, 1992; Näätänen and Winkler, 1999; Näätänen et al, 2007)
Negative peak latencies were submitted to repeated measures analysis of variance (ANOVA), with change type, timing, and sequence as within-participants factors
The present study shows that temporal information for the gap stimulus was certainly compressed in sensory memory representation

Summary

Introduction

In order to process continuously changing auditory information over the course of everyday life, the human brain integrates auditory information as a unitary event about every 200 ms This auditory integration duration is called a temporal window of integration (TWI), and it is used to integrate processes as a “sliding window” in the sound representation (Näätänen, 1990, 1992; Näätänen and Winkler, 1999; Näätänen et al, 2007). Sound Representations Are Time-Compressed is observed when stimuli are closely presented within 250 ms interval (Massaro, 1972) These effects are indicating that the integration process was performed in the temporal window about 200 ms (Cowan, 1984; Moore, 2003)

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Discussion

Conclusion