Shared cortical systems for processing of horizontal and vertical sound motion

Journal of Neurophysiology

Volumn 103, Issue 4, 2010, Pages 1896-1904

  Getzmann, Stephan ^a   Lewald, Jörg ^a,b  

^a LEIBNIZ RESEARCH CENTRE FOR WORKING ENVIRONMENT AND HUMAN FACTORS   (Germany)

^b RUHR UNIVERSITY BOCHUM   (Germany)

Author keywords

[No Author keywords available]

Indexed keywords

ADULT; ARTICLE; AUDITORY STIMULATION; BRAIN REGION; ELECTROENCEPHALOGRAPHY; FEMALE; HUMAN; HUMAN EXPERIMENT; INFORMATION PROCESSING; MALE; NORMAL HUMAN; PRIORITY JOURNAL; SOUND;

ACOUSTIC STIMULATION; ADULT; CEREBRAL CORTEX; ELECTROENCEPHALOGRAPHY; ELECTROMAGNETIC PHENOMENA; EVOKED POTENTIALS, AUDITORY; FEMALE; HUMANS; MALE; MIDDLE AGED; MOVEMENT; SOUND; SPACE PERCEPTION; YOUNG ADULT;

EID: 77951216058     PISSN: 00223077     EISSN: 15221598     Source Type: Journal    
DOI: 10.1152/jn.00333.2009     Document Type: Article

References (77)

1. Alain C, Arnott SR, Hevenor SJ, Graham S, Grady CL. "What" and "where" in the human auditory system. Proc Natl Acad Sci USA 98: 12301-12306, 2001. (Pubitemid 32959868)
2. Altman JA, Vaitulevich SF. Auditory image movement in evoked potentials. Electroencephalogr Clin Neurophysiol 75: 323-333, 1990. (Pubitemid 20111469)
3. Arnott SR, Binns MA, Grady CL, Alain C. Assessing the auditory dualpathway model in humans. NeuroImage 22: 401-408, 2004. (Pubitemid 38515849)
4. Baumgart F, Gaschler-Markefski B, Woldorff MG, Heinze HJ, Scheich H. A movement-sensitive area in auditory cortex. Nature 400: 724-726, 1999.
5. Beauchamp MS, Petit L, Ellmore TM, Ingeholm J, Haxby JV. A parametric fMRI study of overt and covert shifts of visuospatial attention. Neuro- Image 14: 310-321, 2001. (Pubitemid 32709546)
6. Berman RA, Colby CL, Genovese CR, Voyvodic JT, Luna B, Thulborn KR, Sweeney JA. Cortical networks subserving pursuit and saccadic eye movements in humans: an fMRI study. Hum Brain Mapp 8: 209-225, 1999.
7. Bidet-Caulet A, Bertrand O. Dynamics of a temporo-fronto-parietal network during sustained spatial or spectral auditory processing. J Cogn Neurosci 17: 1691-1703, 2005.
8. Blauert J. Spatial Hearing: The Psychophysics of Human Sound Localization. Cambridge, MA: MIT Press, 1997.
9. Bremmer F, Schlack A, Shah NJ, Zafiris O, Kubischik M, Hoffmann K-P, Zilles K, Fink GR. Polymodal motion processing in posterior parietal and premotor cortex: a human fMRI study strongly implies equivalencies between humans and monkeys. Neuron 29: 287-296, 2001. (Pubitemid 32108740)
10. Chase SM, Young ED. Limited segregation of different types of sound localization information among classes of units in the inferior colliculus. J Neurosci 25: 7575-7585, 2005.
11. Corbetta M, Miezin FM, Shulman GL, Petersen SE. A PET study of visuospatial attention. J Neurosci 13: 1202-1226, 1993.
12. Corbetta M, Shulman GL. Human cortical mechanisms of visual attention during orienting and search. Philos Trans R Soc Lond B Biol Sci 353: 1353-1362, 1998. (Pubitemid 28398201)
13. Coull JT, Nobre AC. Where and when to pay attention: the neural systems for directing attention to spatial locations and to time intervals as revealed by both PET and fMRI. J Neurosci 18: 7426-7435, 1998.
14. Davis KA. Contralateral effects and binaural interactions in dorsal cochlear nucleus. J Assoc Res Otolaryngol 6: 280-296, 2005.
15. Davis KA, Ramachandran R, May B. Single-unit responses in the inferior colliculus of decerebrate cats. II. Sensitivity to interaural level differences. J Neurophysiol 82: 164-175, 1999. (Pubitemid 29330071)
16. Davis KA, Ramachandran R, May B. Auditory processing of spectral cues for sound localization in the inferior colliculus. J Assoc Res Otolaryngol 4: 148-163, 2003. (Pubitemid 36753766)
17. Ducommun CY, Michel CM, Clarke S, Adriani M, Seeck M, Landis T, Blanke O. Cortical motion deafness. Neuron 43: 765-777, 2004.
18. Ducommun CY, Murray MM, Thut G, Bellmann A, Viaud-Delmon I, Clarke S, Michel CM. Segregated processing of auditory motion and auditory location: an ERP mapping study. NeuroImage 16: 76-88, 2002.
19. Fujiki N, Riederer KAJ, Jousmäki V, Mäkela JP, Hari R. Human cortical representation of virtual auditory space: differences between sound azimuth and elevation. Eur J Neurosci 16: 2207-2213, 2002.
20. Getzmann S. Effect of auditory motion velocity on reaction time and cortical processes. Neuropsychologia 47: 2625-2633, 2009.
21. Getzmann S, Lewald J. Localization of moving sound. Percept Psychophys 69: 1022-1034, 2007.
22. Getzmann S, Lewald J. Effects of natural versus artificial spatial cues on electrophysiological correlates of auditory motion. Hear Res 259: 44-54, 2010.
23. Getzmann S, Lewald J, Guski R. Representational momentum in spatial hearing. Perception 33: 591-599, 2004.
24. Grantham DW. Discrimination of dynamic interaural intensity differences. J Acoust Soc Am 76: 71-76, 1984.
25. Grantham DW. Auditory motion perception via successive "snapshot" analysis (Abstract). In: Sound Localization by Human Observers: Symposium Proceedings. Washington, DC: National Academy of Sciences, 1989, p. 35.
26. Gratton G, Coles MGH, Donchin E. A new method for off-line removal of ocular artifact. Electroencephalogr Clin Neurophysiol 55: 468-484, 1983.
27. Greenblatt RE, Ossadtchi A, Pflieger ME. Local linear estimators for the bioelectromagnetic inverse problem. IEEE Trans Signal Proc 53: 3403-3412, 2005.
28. Griffiths TD, Green GG. Cortical activation during perception of a rotating wide-field acoustic stimulus. NeuroImage 10: 84-90, 1999.
29. Griffiths TD, Green GG, Rees A, Rees G. Human brain areas involved in the analysis of auditory movement. Hum Brain Mapp 9: 72-80, 2000.
30. Griffiths TD, Rees G, Rees A, Green GG, Witton C, Rowe D, Büchel C, Turner R, Frackowiak RS. Right parietal cortex is involved in the perception of sound movement in humans. Nat Neurosci 1: 74-79, 1998.
31. Griffiths TD, Rees A, Witton C, Shakir RA, Henning GB, Green GG. Evidence for a sound movement area in the human cerebral cortex. Nature 383: 425-427, 1996.
32. Grosbras MH, Laird AR, Paus T. Cortical regions involved in eye movements, shifts of attention, and gaze perception Hum Brain Mapp 25: 140-154, 2005.
33. Hall DA, Hart HC, Johnsrude IS. Relationships between human auditory cortical structure and function. Audiol Neurootol 8: 1-18, 2003.
34. Hirnstein M, Hausmann M, Lewald J. Functional cerebral asymmetry in auditory motion perception. Laterality 12: 87-99, 2007.
35. Holmes AP, Blair RC, Watson JDG, Ford I. Non-parametric analysis of statistic images from functional mapping experiments. J Cereb Blood Flow Metab 16: 7-22, 1996.
36. Imig TJ, Bibikov NG, Poirier P, Samson FK. Directionality derived from pinna-cue spectral notches in cat dorsal cochlear nucleus. J Neurophysiol 83: 907-925, 2000.
37. Jerger J, Estes R. Asymmetry in event-related potentials to simulated auditory motion in children, young adults, and seniors. J Am Acad Audiol 13: 1-13, 2002.
38. Krumbholz K, Eickhoff SB, Fink GR. Feature- and object-based attentional modulation in the human auditory "where" pathway. J Cogn Neurosci 19: 1721-1733, 2007b.
39. Krumbholz K, Hewson-Stoate N, Schönwiesner M. Cortical response to auditory motion suggests an asymmetry in the reliance on interhemispheric connections between the left and right auditory cortices. J Neurophysiol 97: 1649-1655, 2007a.
40. Krumbholz K, Nobis E, Weathritt R, Fink GR. Executive control of spatial attention shifts in the auditory compared to the visual modality. Hum Brain Mapp 30: 1457-1469, 2009.
41. Krumbholz K, Schönwiesner M, Rübsamen R, Zilles K, Fink GR, von Cramon DY. Hierarchical processing of sound location and motion in the human brainstem and planum temporale. Eur J Neurosci 21: 230-238, 2005.
42. Law I, Svarer C, Holm S, Paulson OB. The activation pattern in normal humans during suppression, imagination and performance of saccadic eye movements. Acta Physiol Scand 161: 419-434, 1997.
43. Lewald J, Peters S, Corballis MC, Hausmann M. Perception of stationary and moving sound following unilateral cortectomy. Neuropsychologia 47: 962-971, 2009a.
44. Lewald J, Riederer KA, Lentz T, Meister IG. Processing of sound location in human cortex. Eur J Neurosci 27: 1261-1270, 2008.
45. Lewald J, Städtgen M, Sparing R, Meister IG. Cortical processing of auditory motion investigated by repetitive transcranial magnetic stimulation (Abstract). Proc 3rd Int Conf Auditory Cortex Curr Concepts Hum Anim Res August 29-September 2, 2009, Magdeburg, Germany, 2009b, p. 108-109.
46. Lewald J, Wienemann M, Boroojerdi B. Shift in sound localization induced by rTMS of the posterior parietal lobe. Neuropsychologia 42: 1598-1607, 2004.
47. Lewis JW, Beauchamp MS, DeYoe EA. A comparison of visual and auditory motion processing in human cerebral cortex. Cereb Cortex 10: 873-888, 2000.
48. Mäkelä JP, McEvoy L. Auditory evoked fields to illusory sound source movements. Exp Brain Res 110: 446-454, 1996.
49. Manly BFJ. Randomization, Bootstrap and Monte Carlo Methods in Biology (3rd ed.). Boca Raton, FL: CRC Press, 2007.
50. Marco-Pallares J, Grau C, Ruffini G. Combined ICA-LORETA analysis of mismatch negativity. NeuroImage 25: 471-477, 2005.
51. Mateeff S, Hohnsbein J. Dynamic auditory localization: perceived position of a moving sound source. Acta Physiol Pharmacol Bulg 14: 32-38, 1988.
52. McAlpine D, Jiang D, Shackleton TM, Palmer AR. Responses of neurons in the inferior colliculus to dynamic interaural phase cues: evidence for a mechanism of binaural adaptation. J Neurophysiol 83: 1356-1365, 2000.
53. Nichols TE, Holmes AP. Nonparametric permutation tests for functional neuroimaging: a primer with examples. Hum Brain Map 15: 1-25, 2001.
54. Nobre AC, Sebetyen GN, Gitelman DR, Mesulam MM, Frackowiak RSJ, Frith CD. Functional localisation of the system for visuospatial attention using positron emission tomography. Brain 120: 515-533, 1997.
55. Pascual-Marqui RD. Standardized low-resolution brain electromagnetic tomography (sLORETA): technical details. Methods Find Exp Clin Pharmacol 24, Suppl. D: 5-12, 2002.
56. Pascual-Marqui RD, Lehmann D, Koenig T, Kochi K, Merlo MCG, Hell D, Koukkou M. Low resolution brain electromagnetic tomography (LORETA) functional imaging in acute, neuroleptic-naive, first-episode, productive schizophrenia. Psychiatry Res 90: 169-179, 1999.
57. Pavani F, Macaluso E, Warren JD, Driver J, Griffiths TD. A common cortical substrate activated by horizontal and vertical sound movement in the human brain. Curr Biol 12: 1584-1590, 2002.
58. Perry RJ, Zeki S. The neurology of saccades and covert shifts in spatial attention: an event-related fMRI study. Brain 123: 2273-2288, 2000.
59. Pinek B, Duhamel J-R, Cavé C, Brouchon M. Audio-spatial deficits in humans: differential effects associated with left versus right hemisphere parietal damage. Cortex 25: 175-186, 1989.
60. Poirier C, Collignon O, DeVolder AG, Renier L, Vanlierde A, Tranduy D, Scheiber C. Specific activation of the V5 brain area by auditory motion processing: an fMRI study. Cogn Brain Res 25: 650-658, 2005.
61. Ramachandran R, Davis KA, May BJ. Single-unit responses in the inferior colliculus of decerebrate cats. I. Classification based on frequency response maps. J Neurophysiol 82: 152-163, 1999.
62. Reiss LJ, Young ED. Encoding of rising spectral edges by neural circuits in the dorsal cochlear nucleus. J Neurosci 25: 3680-3691, 2005.
63. Saberi K, Perrott DR. Minimum audible movement angles as a function of sound source trajectory. J Acoust Soc Am 88: 2639-2644, 1990.
64. Schröger E. Interaural time and level differences: integrated or separated processing? Hear Res 96: 191-198, 1996.
65. Sheliga BM, Riggio L, Rizzolatti G. Orienting of attention and eye movements. Exp Brain Res 98: 507-522, 1994.
66. Smith KR, Okada K, Saberi K, Hickok G. Human cortical auditory motion areas are not motion selective. Neuroreport 15: 1523-1526, 2004.
67. Smith KR, Saberi K, Hickok G. An event-related fMRI study of auditory motion perception: no evidence for a specialized cortical system. Brain Res 1150: 94-99, 2007.
68. Spitzer MW, Semple MN. Interaural phase coding in auditory midbrain: influence of dynamic stimulus features. Science 254: 721-723, 1991.
69. Talairach J, Tournoux P. Co-Planar Stereotaxic Atlas of the Human Brain. 3-Dimensional Proportional System: An Approach to Cerebral Imaging. New York: Thieme, 1988.
70. Tardif E, Murray MM, Meylan R, Spierer L, Clarke S. The spatio-temporal brain dynamics of processing and integrating sound localization cues in humans. Brain Res 1092: 161-176, 2006.
71. Tollin DJ. The lateral superior olive: a functional role in sound source localization. Neuroscientist 9: 127-143, 2003.
72. Toronchuk JM, Stumpf E, Cynader MS. Auditory cortex neurons sensitive to correlates of auditory motion: underlying mechanisms. Exp Brain Res 88: 169-180, 1992.
73. Ungan P, Yagcioglu S, Goksoy C. Differences between the N1 waves of the responses to interaural time and intensity disparities: scalp topography and dipole sources. Clin Neurophysiol 112: 485-498, 2001.
74. Warren JD, Zielinski BA, Green GGR, Rauschecker JP, Griffiths TD. Perception of sound-source motion by the human brain. Neuron 34: 139-148, 2002.
75. Xiang J, Chuang S, Wilson D, Otsubo H, Pang E, Holowka S, Sharma R, Ochi A, Chitoku S. Sound motion evoked magnetic fields. Clin Neurophysiol 113: 1-9, 2002.
76. Young ED, Spirou GA, Rice JJ, Voigt HF. Neural organization and responses to complex stimuli in the dorsal cochlear nucleus. Philos Trans R Soc Lond B Biol Sci 336: 407-413, 1992.
77. Zatorre RJ, Bouffard M, Ahad P, Belin P. Where is "where" in the human auditory cortex? Nat Neurosci 5: 905-909, 2002.