- PII
- S3034615025030025-1
- DOI
- 10.7868/S3034615025030025
- Publication type
- Article
- Status
- Published
- Authors
- Volume/ Edition
- Volume 51 / Issue number 3
- Pages
- 14-27
- Abstract
- This study investigated the effect of simultaneous masking at different angular distances between stationary maskers and signals with delayed motion onset on the perceived location of signal trajectory endpoints and the strength of the global field power (GFP) in evoked responses in the electroencephalogram. Stimulus positions were manipulated through interaural intensity differences. Evoked responses to the signal's onset and offset were maximally suppressed when the masker position matched the signal’s starting and ending points, respectively. As the distance increased, the responses partially recovered, indicating a spatial release from masking. The maximum suppression of the motion onset response occurred when the lateral or central masker was located at the end of the movement trajectory. Despite complete or partial suppression of the GFP, the listeners were able to localize the test signals under masking conditions. However, the perceived signal trajectories shortened, and their perceived positions shifted away from the masker. The GFPs were more susceptible to energetic masking, while behavioral responses were more robust in recognizing motion, as they relied on the activity of broad neural networks involved in the integration of sensory information over a longer time period.
- Keywords
- слуховые вызванные потенциалы мощность глобального поля ответ на начало движения пространственная маскировка
- Date of publication
- 02.06.2025
- Year of publication
- 2025
- Number of purchasers
- 0
- Views
- 50
References
- 1. Litovsky R.Y. Spatial release from masking // Acoust. Today. 2012. V. 8. P. 18.
- 2. Yonovitz A., Thompson C.L., Lozar J. Masking level differences: Auditory evoked responses with homophasic and antiphasic signal and noise // J. Speech Hear. Res. 1979. V. 22. № 2. P. 403.
- 3. Вайтулевич С.Ф., Мальцева Н.В. Отражение бинаурального освобождения от маскировки в длиннолатентных слуховых вызванных потенциалах человека // Физиология человека. 1987. Т. 13. № 2. С. 186.
- 4. Vaitulevich S.F., Maltseva N.V. Reflection of binaural release from masking in long-latency auditory evoked potentials in humans // Fiziologiya Cheloveka. 1987. V. 13. № 2. P. 186.
- 5. Lewald J., Getzmann S. Electrophysiological correlates of cocktail-party listening // Behav. Brain Res. 2015. V. 292. P. 157.
- 6. Szalárdy O., Tóth B., Farkas D. et al. Neuronal correlates of informational and energetic masking in the human brain in a multi-talker situation // Front. Psychol. 2019. V. 10. P. 786.
- 7. Альтман Я.А., Вайтулевич С.Ф. Слуховые вызванные потенциалы человека и локализация источника звука. СПб.: Наука, 1992. 136 с.
- 8. Altman Ya.A., Vaitulevich S.F. [Auditory evoked potentials in humans and sound source localization]. SPb.: Nauka, 1992. 136 p.
- 9. Варфоломеев А.Л., Старостина Л.В. Слуховые вызванные потенциалы человека при иллюзорном движении звукового образа // Рос. физиол. журн. им. И.М. Сеченова. 2006. Т. 92. № 9. С. 1046.
- 10. Varfolomeev A.L., Starostina L.V. [Auditory event-related potentials to the apparent auditory image motion] // Ross. Fiziol. Zh. Im. I.M. Sechenova. 2006. V. 92. № 9. P. 1046.
- 11. Krumbholz K., Hewson-Stoate N., Schönwiesner M. Cortical response to auditory motion suggests an asymmetry in the reliance on inter-hemispheric connections between the left and right auditory cortices // J. Neurophysiol. 2007. V. 97. № 2. P. 1649.
- 12. Getzmann S. Effect of auditory motion velocity on reaction time and cortical processes // Neuropsychologia. 2009. V. 47. № 12. P. 2625.
- 13. Shestopalova L.B., Petropavlovskaia E.A., Semenova V.V., Nikitin N.I. Brain Oscillations evoked by sound motion // Brain Res. 2021. V. 1752. P. 147232.
- 14. Семенова В.В., Шестопалова Л.Б., Петропавловская Е.А. и др. Латентность вызванного потенциала как показатель интегрирования акустической информации о движении звука // Физиология человека. 2022. Т. 48. № 4. С. 57.
- 15. Semenova V.V., Shestopalova L.B., Petropavlovskaya E.A. et al. Latency of motion onset response as an integrative measure of processing sound movement // Human Physiology. 2022. V. 48. № 4. P. 401.
- 16. Getzmann S., Lewald J. Effects of natural versus artificial spatial cues on electrophysiological correlates of auditory motion // Hear. Res. 2010. V. 259. № 1-2. P. 44.
- 17. Shestopalova L.B., Petropavlovskaia E.A., Salikova D.A., Semenova V.V. Temporal integration of sound motion: Motion-onset response and perception // Hear. Res. 2024. V. 441. P. 108922.
- 18. Шестопалова Л.Б., Петропавловская Е.А., Саликова Д.А. и др. Слуховые вызванные потенциалы человека в условиях пространственной маскировки // Физиология человека. 2022. Т. 48. № 6. С. 32.
- 19. Shestopalova L.B., Petropavlovskaia E.A., Salikova D.A. et al. Event-related potentials in conditions of auditory spatial masking in humans // Human Physiology. 2022. V. 48. № 6. P. 633.
- 20. Петропавловская Е.А., Шестопалова Л.Б., Саликова Д.А., Семенова В.В. Вызванные потенциалы мозга человека на выключение звука в условиях пространственной маскировки // Ж. высш. нервн. деят. им. И.П. Павлова. 2023. Т. 73. № 6. С. 735.
- 21. Petropavlovskaia E.A., Shestopalova L.B., Salikova D.A., Semenova V.V. [Offset responses in conditions of auditory spatial masking in humans] // Zh. Vyssh. Nervn. Deyat. Im. I.P. Pavlova 2023. V. 73. № 6. P. 735.
- 22. Петропавловская Е.А., Шестопалова Л.Б., Саликова Д.А. Локализация движущихся звуковых стимулов в условиях пространственной маскировки // Физиология человека. 2024. Т. 50. № 2. С. 43.
- 23. Petropavlovskaia E.A., Shestopalova L.B., Salikova D.A. Localization of moving sound stimuli under conditions of spatial masking // Human Physiology. 2024. V. 50. № 2. P. 116.
- 24. Альтман Я.А. Пространственный слух. СПб.: Институт физиологии им. И.П. Павлова РАН, 2011. 311 с.
- 25. Altman Ya.A. [Spatial hearing]. SPb.: Institut fiziologii im. I.P. Pavlova RAN, 2011. 311 p.
- 26. Delorme A., Sejnowski T., Makeig S. Enhanced detection of artifacts in EEG data using higher-order statistics and independent component analysis // Neuroimage. 2007. V. 34. № 4. P. 1443.
- 27. Skrandies W. Data reduction of multichannel fields: Global field power and principal component analysis // Brain Topogr. 1989. V. 2. № 1-2. P. 73.
- 28. Somervail R., Zhang F., Novembre G. et al. Waves of change: Brain sensitivity to differential, not absolute, stimulus intensity is conserved across humans and rats // Cereb. Cortex. 2021. V. 31. № 2. P. 949.
- 29. Salminen N.H., Tiitinen H., May P.J.C. Auditory spatial processing in the human cortex // Neuroscientist. 2012. V. 18. № 6. P. 602.
- 30. Magezi D.A., Krumbholz K. Evidence for opponent-channel coding of interaural time differences in human auditory cortex // J. Neurophysiol. 2010. V. 104. № 4. P. 1997.
- 31. Briley P.M., Kitterick P.T., Summerfield A.Q. Evidence for opponent process analysis of sound source location in humans // J. Assoc. Res. Otolaryngol. 2013. V. 14. № 1. P. 83.
- 32. Altmann C.F., Ueda R., Bucher B. et al. Trading of dynamic interaural time and level difference cues and its effect on the auditory motion-onset response measured with electroencephalography // NeuroImage. 2017. V. 159. P. 185.
- 33. Papesh M.A., Folmer R.L., Gallun F.J. Cortical measures of binaural processing predict spatial release from masking performance // Front. Hum. Neurosci. 2017. V. 11. P. 124.
- 34. Karanasiou I.S., Papageorgiou C., Kyprianou M. et al. Effect of frequency deviance direction on performance and mismatch negativity // J.Integr. Neurosci. 2011. V. 10. № 4. P. 525.
- 35. Peter V., McArthur G., Thompson W.F. Effect of deviance direction and calculation method on duration and frequency mismatch negativity (MMN) // Neurosci. Lett. 2010. V. 482. № 1. P. 71.
- 36. Shestopalova L.B., Petropavlovskaia E.A., Semenova V.V., Nikitin N.I. Mismatch negativity and psychophysical detection of rising and falling intensity sounds // Biol. Psychol. 2018. V. 133. P. 99.
- 37. Yost W.A. The cocktail party effect: 40 years later / Localization and spatial hearing in real and virtual environments // Eds. Gilkey R., Anderson T. Erlbaum Press, Mahwah, NJ, 1997. P. 329.
- 38. Yost W.A., Brown C.A. Localizing the sources of two independent noises: Role of time varying amplitude differences // J. Acoust. Soc. Am. 2013. V. 133. № 4. P. 2301.
- 39. Zhong X., Yost W.A. How many images are in an auditory scene? // J. Acoust. Soc. Am. 2017. V. 141. № 4. P. 2882.
- 40. Arbogast T.L., Mason C.R., Kidd G. Jr. The effect of spatial separation on informational and energetic masking of speech // J. Acoust. Soc. Am. 2002. V. 112. № 5. Pt. 1. P. 2086.
- 41. Kidd G. Jr., Mason C.R., Swaminathan J. et al. Determining the energetic and informational components of speech-on-speech masking // J. Acoust. Soc. Am. 2016. V. 140. № 1. P. 132.