Neural representations of complex temporal modulations in the human auditory cortex

Journal of Neurophysiology

Volumn 102, Issue 5, 2009, Pages 2731-2743

  Ding, Nai ^a   Simon, Jonathan Z ^a,b  

^a UNIVERSITY OF MARYLAND   (United States)

^b Bldg 142   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

ADULT; AMPLITUDE MODULATION; ARTICLE; AUDITORY CORTEX; AUDITORY STIMULATION; CONTROLLED STUDY; FEMALE; FREQUENCY MODULATION; HUMAN; MAGNETOENCEPHALOGRAPHY; MALE; NERVE CELL NETWORK; NERVE POTENTIAL; PRIORITY JOURNAL;

ACOUSTIC STIMULATION; ADOLESCENT; ADULT; AUDITORY CORTEX; AUDITORY PERCEPTION; BRAIN MAPPING; COMPUTER SIMULATION; FEMALE; HUMANS; MAGNETOENCEPHALOGRAPHY; MALE; MODELS, NEUROLOGICAL; NEURONS; NONLINEAR DYNAMICS; PSYCHOACOUSTICS; REACTION TIME; SOUND; YOUNG ADULT;

EID: 70449394560     PISSN: 00223077     EISSN: 15221598     Source Type: Journal    
DOI: 10.1152/jn.00523.2009     Document Type: Article

References (58)

1. Bendor D, Wang X. Differential neural coding of acoustic flutter within primate auditory cortex. Nat Neurosci 10: 763-771, 2007. (Pubitemid 46828501)
2. Boemio A, Fromm S, Braun A, Poeppel D. Hierarchical and asymmetric temporal sensitivity in human auditory cortices. Nat Neurosci 8: 389-395, 2005. (Pubitemid 40300197)
3. Chi T, Gao Y, Guyton MC, Ru P, Shamma S. Spectro-temporal modulation transfer functions and speech intelligibility. J Acoust Soc Am 106: 2719-2732, 1999. (Pubitemid 129520435)
4. Dau T, Kollmeier B, Kohlrausch A. Modeling auditory processing of amplitude modulation. II. Spectral and temporal integration. J Acoust Soc Am 102: 2906-2919, 1997. (Pubitemid 27486268)
5. Dau T, Puschel D, Kohlrausch A. A quantitative model of the "effective" signal processing in the auditory system. I. Model structure. J Acoust Soc Am 99: 3615-3622, 1996. (Pubitemid 26190250)
6. de Boer E. Auditory time constants: a paradox? In: Time Resolution in Auditory Systems, edited by Michelsen A. Berlin: Springer, 1985, p. 141-158.
7. de Cheveigné A, Simon JZ. Denoising based on time-shift PCA. J Neurosci Methods 165: 297-305, 2007.
8. de Cheveigné A, Simon JZ. Denoising based on spatial filtering. J Neurosci Methods 171: 331-339, 2008a.
9. de Cheveigné A, Simon JZ. Sensor noise suppression. J Neurosci Methods 168: 195-202, 2008b.
10. Dimitrijevic A, John MS, van Roon P, Picton TW. Human auditory steady-state responses to tones independently modulated in both frequency and amplitude. Ear Hear 22: 100-111, 2001. (Pubitemid 32290035)
11. Draganova R, Ross B, Borgmann C, Pantev C. Auditory cortical response patterns to multiple rhythms of AM sound. Ear Hear 23: 254-265, 2002. (Pubitemid 34625514)
12. Drullman R, Festen JM, Plomp R. Effect of temporal envelope smearing on speech reception. J Acoust Soc Am 95: 1053-1064, 1994. (Pubitemid 24056370)
13. Eggermont JJ. Temporal modulation transfer functions in cat primary auditory cortex: separating stimulus effects from neural mechanisms. J Neurophysiol 87: 305-321, 2002.
14. Elhilali M, Fritz JB, Klein DJ, Simon JZ, Shamma SA. Dynamics of precise spike timing in primary auditory cortex. J Neurosci 24: 1159-1172, 2004. (Pubitemid 38177023)
15. Ewert SD, Verhey JL, Dau T. Spectro-temporal processing in the envelopefrequency domain. J Acoust Soc Am 112: 2921-2931, 2002.
16. Fisher NI. Statistical Analysis of Circular Data. New York: Cambridge, 1993.
17. Friesen LM, Shannon RV, Baskent D, Wang X. Speech recognition in noise as a function of the number of spectral channels: comparison of acoustic hearing and cochlear implants. J Acoust Soc Am 110: 1150-1163, 2001. (Pubitemid 32734748)
18. Fujiki N, Jousmaki V, Hari R. Neuromagnetic responses to frequency-tagged sounds: a new method to follow inputs from each ear to the human auditory cortex during binaural hearing. J Neurosci 22: 205RC, 2002.
19. Fullgrabe C, Lorenzi C. Perception of the envelope-beat frequency of inharmonic complex temporal envelopes. J Acoust Soc Am 118: 3757-3765, 2005. (Pubitemid 41820876)
20. Gaese BH, Ostwald J. Temporal coding of amplitude and frequency modulation in the rat auditory cortex. Eur J Neurosci 7: 438-450, 1995.
21. Giraud A-L, Kleinschmidt A, Poeppel D, Lund TE, Frackowiak RSJ, Laufs H. Endogenous cortical rhythms determine cerebral specialization for speech perception and production. Neuron 56: 1127-1134, 2007. (Pubitemid 350251110)
22. Giraud A-L, Lorenzi C, Ashburner J, Wable J, Johnsrude I, Frackowiak R, Kleinschmidt A. Representation of the temporal envelope of sounds in the human brain. J Neurophysiol 84: 1588-1598, 2000. (Pubitemid 30688179)
23. Greenberg S, Carvey H, Hitchcock L, Chang S. Temporal properties of spontaneous speech-a syllable-centric perspective. J Phon 31: 465-485, 2003. (Pubitemid 37495920)
24. Hart HC, Palmer AR, Hall DA. Amplitude and frequency-modulated stimuli activate common regions of human auditory cortex. Cereb Cortex 13: 773-781, 2003.
25. John MS, Dimitrijevic A, Roon PV, Picton TW. Multiple auditory steadystate responses to AM and FM stimuli. Audiol Neurootol 6: 12-27, 2001. (Pubitemid 32098417)
26. John MS, Picton TW. MASTER: a Windows program for recording multiple auditory steady-state responses. Comput Methods Programs Biomed 61: 125-150, 2000.
27. Joris PX, Schreiner CE, Rees A. Neural processing of amplitude-modulated sounds. Physiol Rev 84: 541-577, 2004.
28. Lakatos P, Shah AS, Knuth KH, Ulbert I, Karmos G, Schroeder CE. An oscillatory hierarchy controlling neuronal excitability and stimulus processing in the auditory cortex. J Neurophysiol 94: 1904-1911, 2005.
29. Liang L, Lu T, Wang X. Neural representations of sinusoidal amplitude and frequency modulations in the primary auditory cortex of awake primates. J Neurophysiol 87: 2237-2261, 2002. (Pubitemid 34670698)
30. Liegeois-Chauvel C, Lorenzi C, Trebuchon A, Regis J, Chauvel P. Temporal envelope processing in the human left and right auditory cortices. Cereb Cortex 14: 731-740, 2004. (Pubitemid 38856948)
31. Lorenzi C, Gilbert G, Carn H, Garnier S, Moore BCJ. Speech perception problems of the hearing impaired reflect inability to use temporal fine structure. Proc Natl Acad Sci USA 103: 18866-18869, 2006. (Pubitemid 44913501)
32. Lorenzi C, Simpson MIG, Millman RE, Griffiths TD, Woods WP, Rees A, Green GGR. Second-order modulation detection thresholds for pure-tone and narrow-band noise carriers. J Acoust Soc Am 110: 2470-2478, 2001a. (Pubitemid 33064115)
33. Lorenzi C, Soares C, Vonner T. Second-order temporal modulation transfer functions. J Acoust Soc Am 110: 1030-1038, 2001b. (Pubitemid 32734737)
34. Luo H, Wang Y, Poeppel D, Simon JZ. Concurrent encoding of frequency and amplitude modulation in human auditory cortex: MEG evidence. J Neurophysiol 96: 2712-2723, 2006. (Pubitemid 44785918)
35. Luo H, Wang Y, Poeppel D, Simon JZ. Concurrent encoding of frequency and amplitude modulation in human auditory cortex: encoding transition. J Neurophysiol 98: 3473-3485, 2007. (Pubitemid 44785918)
36. Ménard M, Gallégo S, Berger-Vachon C, Collet L, Thai-Vana H. Relationship between loudness growth function and auditory steady-state response in normal-hearing subjects. Hear Res 235: 105-113, 2008.
37. Millman RE, Prendergast G, Kitterick PT, Woods WP, Green GGR. Spatiotemporal reconstruction of the auditory steady-state response to frequency modulation using magnetoencephalography. NeuroImage (August 21, 2009). doi:10.1016/j.neuroimage.2009.08.029.
38. Moore BCJ. Introduction to the Psychology of Hearing. Boston, MA: Academic Press, 2003.
39. Moore BCJ, Sek A. Detection of frequency modulation at low modulation rates: evidence for a mechanism based on phase locking. J Acoust Soc Am 100: 2320-2331, 1996. (Pubitemid 126676135)
40. Moore BCJ, Vickers DA, Baer T, Launer S. Factors affecting the loudness of modulated sounds. J Acoust Soc Am 105: 2757-2772, 1999. (Pubitemid 29218395)
41. Näätänen R, Picton T. The N1 wave of the human electric and magnetic response to sound: a review and an analysis of the component structure. Psychophysiology 24: 375-425, 1987. (Pubitemid 17114207)
42. Picton TW, Skinner CR, Champagne SC, Kellett AJC, Maiste AC. Potentials evoked by the sinusoidal modulation of the amplitude or frequency of a tone. J Acoust Soc Am 82: 165-178, 1987.
43. Poeppel D. The analysis of speech in different temporal integration windows: cerebral lateralization as 'asymmetric sampling in time'. Speech Commun 41: 245-255, 2003.
44. Poulsen C, Picton TW, Paus T. Age-related changes in transient and oscillatory brain responses to auditory stimulation in healthy adults 19-45 years old. Cereb Cortex 17: 1454-1467, 2007. (Pubitemid 47343631)
45. Remez RE, Rubin PE, Pisoni DB, Carrell TD. Speech perception without traditional speech cues. Science 212: 947-950, 1981.
46. Rosen S. Temporal information in speech: acoustic, auditory and linguistic aspects. Philos Trans R Soc Lond B Biol Sci 336: 367-373, 1992.
47. Ross B, Borgmann C, Draganova R, Roberts LE, Pantev C. A highprecision magnetoencephalographic study of human auditory steady-state responses to amplitude-modulated tones. J Acoust Soc Am 108: 679-691, 2000. (Pubitemid 30625892)
48. Ross B, Draganova R, Picton TW, Pantev C. Frequency specificity of 40-Hz auditory steady-state responses. Hear Res 186: 57-68, 2003. (Pubitemid 37476449)
49. Ross B, Herdman AT, Pantev C. Stimulus induced desynchronization of human auditory 40-Hz steady-state responses. J Neurophysiol 94: 4082-4093, 2005. (Pubitemid 41691770)
50. Ross B, Pantev C. Auditory steady-state responses reveal amplitude modulation gap detection thresholds. J Acoust Soc Am 115: 2193-2206, 2004. (Pubitemid 38542134)
51. Ross B, Picton TW, Pantev C. Temporal integration in the human auditory cortex as represented by the development of the steady-state magnetic field. Hear Res 165: 68-84, 2002. (Pubitemid 34553399)
52. Saberi K, Hafter ER. A common neural code for frequency- and amplitudemodulated sounds. Nature 374: 537-539, 1995.
53. Shamma S. Analysis of speech dynamics in the auditory system. In: Dynamics of Speech Production and Perception: Life and Behavioural Sciences, edited by Divenyi P, Greenberg S, Meyer G. Washington, DC: IOS Press, 2006, p. 335-342.
54. Shannon RV, Zeng F-G, Kamath V, Wygonski J, Ekelid M. Speech recognition with primarily temporal cues. Science 270: 303-304, 1995.
55. Viemeister NF. Temporal modulation transfer functions based upon modulation thresholds. J Acoust Soc Am 66: 1364-1380, 1979.
56. Viemeister NF, Wakefield GH. Temporal integration and multiple looks. J Acoust Soc Am 90: 858-865, 1991.
57. Wang X, Lu T, Liang L. Cortical processing of temporal modulations. Speech Commun 41: 107-121, 2003.
58. Zeng F-G, Nie K, Stickney GS, Kong Y-Y, Vongphoe M, Bhargave A, Wei C, Cao K. Speech recognition with amplitude and frequency modulations. Proc Natl Acad Sci USA 102: 2293-2298, 2005. (Pubitemid 40279369)