Topography of Activity Evoked in the Human Brain during Discrimination of Moving Sound Stimuli

被引：0

作者：

Shestopalova L.B. ^{[1
]}

Petropavlovskaya E.A. ^{[1
]}

Vaitulevich S.F. ^{[1
]}

Nikitin N.I. ^{[1
]}

机构：

[1] Pavlov Institute of Physiology, Russian Academy of Sciences, St. Petersburg

来源：

Neuroscience and Behavioral Physiology | 2017年 / 47卷 / 1期

关键词：

event-related potentials; interhemisphere asymmetry; mismatch negativity; sound stimulus movement; spatial hearing;

D O I：

10.1007/s11055-016-0368-9

中图分类号：

学科分类号：

摘要：

The aim of the present work was to assess interhemisphere asymmetry of the N1, P2, and N250 components of auditory event-related potentials (ERP) and mismatch negativity (MMN) in passive discrimination between moving sound stimuli in an oddball paradigm. Stimulus movement was created using a linear increase in the interaural time delay ΔT in dichotically presented signals. The amplitudes of the N1 and P2 components were greater in the right hemisphere, this being particularly clear in the frontolateral area. The amplitude of the N250 component in the frontolateral and frontomedial areas was greater in the hemisphere contralateral to the sound stimulus. The direction of movement of sound stimuli had no effect on the asymmetry of ERP and MMN components. The right-hemisphere asymmetry of N1 increased with increases in stimulus speed, while asymmetry of P2 was maximal for short movement trajectories. Asymmetry of N250 and MMN was identified in terms of differences between standards and deviants, i.e., a higher-order feature. Thus, these studies demonstrated differences in the nature of interhemisphere asymmetry for the early and late ERP components, reflecting differences in the neural structures supporting primary analysis of the stimulus and higher cognitive processes. © 2016, Springer Science+Business Media New York.

引用

页码：83 / 96

页数：13

共 44 条

[1]

Alain C., Woods D.L., Knight R., A distributed cortical network for auditory sensory memory in humans, Brain Res., 812, pp. 23-37, (1998)

[2]

Alain C., Woods D.L., Ogawa K., H., “Brain indices of automatic pattern processing, Neuroreport, 6, 1, pp. 140-144, (1994)

[3]

Altman J.A., Vaitulevich S., P., Shestopalova, L. B., and Petropavlovskaia, E. A., “How does mismatch negativity refl ect auditory motion?” Hear. Res., 268, pp. 194-201, (2010)

[4]

Baumgart F., Gaschler-Markefski B., Woldorff M.G., Et al., A movement-sensitive area in auditory cortex, Nature, 400, pp. 724-726, (1999)

[5]

Briley P.M., Kitterick P.T., Summerfield A.Q., Evidence for opponent process analysis of sound source location in humans, J. Assoc. Res. Otolaryngol., 14, 1, pp. 83-101, (2013)

[6]

Brunetti M., Belardinelli P., Caulo M., Et al., Human brain activation during passive listening to sounds from different locations: an fMRI and MEG study, Hum. Brain Mapp., 26, pp. 251-261, (2005)

[7]

Deouell L., Y., Bentin, S., and Giard, M. H., “Mismatch negativity in dichotic listening: Evidence for interhemispheric differences and multiple generators, Psychophysiol., 35, 4, pp. 355-365, (1998)

[8]

Deouell L., Y., Bentin, S., and Soroker, N., “Electrophysiological evidence for an early (pre-attentive) information processing deficit in patients with right hemisphere damage and unilateral neglect, Brain, 123, 2, pp. 353-365, (2000)

[9]

Escera C., Alho K., Winkler I., Naatanen R., Neural mechanisms of involuntary attention to acoustic novelty and change, J. Cogn. Neurosci., 10, 5, pp. 590-604, (1998)

[10]

Getzmann S., Lewald J., Effects of natural versus artificial spatial cues on electrophysiological correlates of auditory motion, Hear. Res., 259, pp. 44-54, (2010)

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