Physiological measurements of human binaural processing

Forfattere

  • Terence W. Picton Rotman Research Institute, Baycrest Centre, University of Toronto, Toronto, Canada
  • Bernhard Ross Rotman Research Institute, Baycrest Centre, University of Toronto, Toronto, Canada

Resumé

Many different electric and magnetic responses to sound can be recorded as the human brain processes binaural information: (1) A binaural interaction component can be measured by comparing binaural responses to the sum of separate monaural responses. (2) Locating sounds in a reverberant environment can be examined by evaluating echo suppression. (3) Binaural beats can evoke following responses. (4) Responses can be evoked by binaural stimuli that are unmasked by changes in the interaural phase of stimulus or noise. (5) Occasional changes in the spatial location of a repeating sound can evoke a mismatch negativity. (6) A change in the binaural characteristics of an ongoing stimulus – interaural timing, correlation or phase – evokes a large N1-P2 response that is later than the response to the onset of a sound. The concomitant disruption and reinstatement of the 40-Hz steady state response can measure temporal perception and integration. (7) Moving sounds evoke large cortical responses when the movement begins and when a moving object crosses the midline. All paradigms may become useful in objectively demonstrating normal or abnormal binaural function in patients who cannot respond reliably during behavioral testing.

Referencer

Alain, C., Arnott, S. R., and Picton, T. W. (2001). “Bottom-up and top-down in uences on auditory scene analysis: Evidence from event-related brain potentials,” J. Exp Psychol. Hum. Percept. Perform. 27, 1072-1089.

Butler, R. A. (1972). “The in uence of spatial separation of sound sources on the auditory evoked response,” Neuropsychologia 10, 219-225.

Butler, R. A., and Kluskens, L. (1971). “The in uence of phase inversion on the auditory evoked response,” Audiology 10, 353-357.

Chait, M., Poeppel, D., de Cheveigné, A., and Simon, J. Z., (2005). “Human auditory cortical processing of changes in interaural correlation,” J. Neurosci. 25, 8518- 8527.

Chait, M., Poeppel, D., and Simon, J. Z. (2007). “Stimulus context affects auditory cortical responses to changes in interaural correlation,” J. Neurophysiol. 98, 224- 231.

Dajani, H. R., and Picton, T. W. (2006). “Human auditory steady-state responses to changes in interaural correlation,” Hear. Res. 219, 85-100.

Damaschke, J., Riedel, H., and Kollmeier, B. (2005). “Neural correlates of the precedence effect in auditory evoked potentials,” Hear. Res. 205, 157-171.

Draganova, R., Ross, B., Wollbrink, A., and Pantev, C. (2008). “Cortical steady- state responses to central and peripheral auditory beats,” Cereb Cortex. 18, 1193- 1200.

Deouell, L. Y., Parnes, A., Pickard, N., and Knight, R. T. (2006). “Spatial location is accurately tracked by human auditory sensory memory: evidence from the mismatch negativity,” Eur J Neurosci. 24, 1488-1494.

Dobie, R. A., and Berlin, C. I., (1979). “Binaural interaction in brainstem-evoked responses,” Arch. Otolaryngol. 105, 391-398.

Dobie, R. A., and Norton, S. J., (1980). “Binaural interaction in human auditory evoked potentials,” Electroencephalogr. Clin. Neurophysiol. 49, 303-313.

Draganova, R., Ross, B., Wollbrink, A., and Pantev, C. (2008). “Cortical steady-state responses to central and peripheral auditory beats,” Cereb Cortex. 18,1193-1200.

Fowler, C. G., and Mikami, C. M. (1992). “Effects of noise bandwidth on the late- potential masking level difference,” Electroencephalogr. Clin. Neurophysiol. 84, 157-163.

Fowler, C. G., and Mikami, C. M. (1995). “Binaural phase effects in the auditory brainstem response,” J. Amer. Acad. Audiol. 6, 399-406.

Galambos, R., Makeig, S. (1992) “Physiological studies of central masking in man. II: Tonepip SSRs and the masking level difference,” J. Acoust. Soc. Am. 92, 2691-2697.

Halliday, R., and Callaway, E. (1978). “Time shift evoked potentials (TSEPs): method and basic results,” Electroencephalogr. Clin. Neurophysiol. 45, 118-121.

Johnson, B. W., Hautus, M., and Clapp, W. C. (2003) “Neural activity associated with binaural processes for the perceptual segregation of pitch,” Clin. Neurophysiol. 114, 2245-2250.

Jones, S. J. (1991). “Memory-dependent auditory evoked potentials to change in the binaural interaction of noise signals,” Electroencephalogr. Clin. Neurophysiol. 80, 399-405.

Jones, S. J., Pitman, J. R., and Halliday, A. M. (1991). “Scalp potentials following sudden coherence and discoherence of binaural noise and change in the inter-aural time difference: a speci c binaural evoked potential or a “mismatch” response?” Electroencephalogr. Clin. Neurophysiol. 80, 146-154.

Kaiser, J., and Bertrand, O. (2003). “Dynamics of working memory for moving sounds: an event-related potential and scalp current density study,” Neuroimage 19, 1427-1438.

Krishnan, A., and McDaniel, S. S. (1998). “Binaural interaction in the human frequency-following response: effects of interaural intensity difference,” Audiol Neurootol. 3, 291-299.

Levine, R. A. (1981). “Binaural interaction in brainstem potentials of human subjects,” Ann Neurol. 9, 384-393.

Li, L., Qi, J., He, Y., Alain, C., and Schneider, B. A. (2005). “Attribute capture in the precedence effect for long-duration noise sounds,” Hear. Res., 202, 235-247.

Liebenthal, E., and Pratt, H. (1999). “Human auditory cortex electrophysiological correlates of the precedence effect: binaural echo lateralization suppression,” J. Acoust. Soc. Am. 106, 291-303.

Lüddemann, H., Riedel, H., and Kollmeier, B. (2009). “Electrophysiological and psychophysical asymmetries in sensitivity to interaural correlation steps,” Hear. Res. 256, 39-57.

May, P. J. C., and Tiitinen, H. (2009). “Mismatch negativity (MMN), the deviance- elicited auditory de ection, explained,” Psychophysiology 47, 66-122.

McEvoy, L. K., Picton, T. W., and Champagne, S. C. (1991). “Effects of stimulus parameters on human evoked potentials to shifts in the lateralization of a noise.” Audiology 30, 286-302.

McEvoy, L. K., Picton, T. W., Champagne, S. C., Kellett, A. J. C., and Kelly, J. B. (1990). “Human evoked potentials to shifts in the lateralization of a noise,” Audiology 29, 163-180.

McPherson, D. L., and Starr, A. (1993). “Binaural interaction in auditory evoked potentials: Brainstem, middle- and long-latency components,” Hear. Res. 66, 91-98.

McPherson, D. L., and Starr, A. (1995). “Auditory time-intensity cues in the binaural interaction component of the auditory evoked potentials,” Hear. Res. 89, 162- 171.

Näätänen, R., Paavilainen, P., Rinne, T., and Alho, K. (2007). “The mismatch negativity (MMN) in basic research of central auditory processing: A review,” Clin. Neurophysiol. 118, 2544-2590.

Paavilainen, P., Karlsson, M. L., Reinikainen, K., and Näätänen, R. (1989). “Mismatch negativity to change in spatial location of an auditory stimulus,” Electroencephalogr. Clin. Neurophysiol. 73, 129-41.

Picton, T. W. (2007). “Audiometry using auditory steady-state responses,” in Auditory Evoked Potentials: Basic Principles and Clinical Applications edited by R. F. Burkard, M. Don and J. J. Eggermont (Lippincott, Williams and Wilkins, Baltimore), pp. 441-462.

Picton, T. W., Rodriguez, R. T., Linden, R. D., and Maiste, A. C. (1985). “The neurophysiology of human hearing,” Human Communication Canada 9, 127- 136.

Pratt, H., Polyakov, A., Aharonson, V., Korczyn, A. D., Tadmor, R., Fullerton, B. C., Levine, R. A., and Furst, M. (1998). “Effects of localized pontine lesions on auditory brain-stem evoked potentials and binaural processing in humans,” Electroencephalogr. Clin. Neurophysiol. 108, 511-520.

Riedel, H., and Kollmeier, B. (2006). “Interaural delay-dependent changes in the binaural difference potential of the human auditory brain stem response,” Hear. Res. 218, 5-19.

Röttger, S., Schröger, E., Grube, M., Grimm, S., and Rübsamen, R. (2007). “Mismatch negativity on the cone of confusion,” Neurosci Lett. 414, 178-182.

Ross, B. (2008). “A novel type of auditory responses: temporal dynamics of 40-Hz steady-state responses induced by changes in sound localization,” J. Neurophysiol. 100, 1265-1277.

Ross, B., Fujioka, T., Tremblay, K. L., and Picton, T. W. (2007a). “Aging in binaural hearing begins in mid-life: Evidence from cortical auditory evoked responses to changes in interaural phase.” J. Neurosci. 27, 11172-11178.

Ross, B., Tremblay, K., and Picton, T. (2007b). “Physiological detection of interaural phase differences,” J. Acoust. Soc. Am. 121, 1017-1027.
Sasaki, T., Kawase, T., Nakasato, N., Kanno, A., Ogura, M., Tominaga, T., and Kobayashi T. (2005). “Neuromagnetic evaluation of binaural unmasking,” Neuroimage 25, 684-689.

Schwarz, D. W., and Taylor, P. (2005). “Human auditory steady state responses to binaural and monaural beats,” Clin. Neurophysiol. 116, 658-668.

Schröger, E., and Wolff, C. (1996). “Mismatch response of the human brain to changes in sound location,” NeuroReport 7, 3005-3008.

Soeta, Y., Hotehama, T., Nakagawa, S., Tonoike, M., and Ando, Y. (2004). “Auditory evoked magnetic elds in relation to interaural cross-correlation of band-pass noise,” Hear. Res. 196, 109-114.

Sonnadara, R. R., Alain, C., and Trainor, L. J. (2006). “Effects of spatial separation and stimulus probability on the event-related potentials elicited by occasional changes in sound location,” Brain Res. 1071, 175-185.

Wilson, J. R., and Krishnan, A. (2005). “Human frequency-following responses to binaural masking level difference stimuli,” J Am Acad Audiol. 16, 184-195.

Wong, Y. S. W., and Stapells, D. R. (2004). “Brain stem and cortical mechanisms underlying the binaural masking level difference in humans: An auditory steady- state response study,” Ear. Hear. 25, 57-67.

Xiang, J., Daniel, S. J., Ishii, R., Holowka, S., Harrison, R. V., and Chuang, S. (2005). “Auditory detection of motion velocity in humans: a magnetoencephalographic study,” Brain Topogr. 17, 139-149.

Zaaroor, M., Bleich, N., Mittelman, N., and Pratt, H. (2003). “Equivalent dipoles of the binaural interaction components and their comparison with binaurally evoked human auditory 40 Hz steady-state evoked potentials,” Ear Hear. 24, 248-256.

Yderligere filer

Publiceret

2009-12-15

Citation/Eksport

Picton, T. W., & Ross, B. (2009). Physiological measurements of human binaural processing. Proceedings of the International Symposium on Auditory and Audiological Research, 2, 15–28. Hentet fra https://proceedings.isaar.eu/index.php/isaarproc/article/view/2009-02

Nummer

Sektion

2009/1. Physiological measures and models of binaural hearing