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Human temporal auditory acuity as assessed by envelope following responses
1.Amitay, S. , Ahissar, M. , and Nelken, I. (2002). “Auditory processing deficits in reading disabled adults,” J. Assoc. Res. Otolaryngol. 3, 302–320.
2.Artieda, J. , Valencia, M. , Alegre, M. , Olaziregi, O. , Urrestarazu, E. , and Iriarte, J. (2004). “Potentials evoked by chirp-modulated tones: A new technique to evaluate oscillatory activity in the auditory pathway,” Clin. Neurophysiol. 115, 699–709.
3.Bacon, S. P. , and Viemeister, N. F. (1985). “Temporal modulation transfer functions in normal-hearing and hearing-impaired listeners,” Audiology 24, 117–134.
4.Benasich, A. A. , and Tallal, P. (2002). “Infant discrimination of rapid auditory cues predicts later language impairment,” Behav. Brain Res. 136, 31–49.
5.Bishop, D. V. , Carlyon, R. P. , Deeks, J. M. , and Bishop, S. J. (1999). “Auditory temporal processing impairment: Neither necessary nor sufficient for causing language impairment in children,” J. Speech Lang. Hear. Res. 42, 1295–1310.
6.Boettcher, F. A. , Madhotra, D. , Poth, E. A. , and Mills, J. H. (2002). “The frequency-modulation following response in young and aged human subjects,” Hear. Res. 165, 10–18.
7.Boettcher, F. A. , Poth, E. A. , Mills, J. H. , and Dubno, J. R. (2001). “The amplitude-modulation following response in young and aged human subjects,” Hear. Res. 153, 32–42.
8.Cohen, L. T. , Rickards, F. W. , and Clark, G. M. (1991). “A comparison of steady-state evoked potentials to modulated tones in awake and sleeping humans,” J. Acoust. Soc. Am. 90, 2467–2479.
9.Dimitrijevic, A. , John, M. S. , and Picton, T. W. (2004). “Auditory steady-state responses and word recognition scores in normal-hearing and hearing-impaired adults,” Ear Hear. 25, 68–84.
10.Dobie, R. A. , and Wilson, M. J. (1998). “Low-level steady-state auditory evoked potentials: Effects of rate and sedation on detectability,” J. Acoust. Soc. Am. 104, 3482–3488.
11.Fitzgibbons, P. J. , and Wightman, F. L. (1982). “Gap detection in normal and hearing-impaired listeners,” J. Acoust. Soc. Am. 72, 761–765.
12.Formby, C. (1987). “Modulation threshold functions for chronically impaired Meniere patients,” Audiology 26, 89–102.
13.Galambos, R. , Makeig, S. , and Talmachoff, P. J. (1981). “A 40-Hz auditory potential recorded from the human scalp,” Proc. Natl. Acad. Sci. U.S.A. 78, 2643–2647.
14.Gordon-Salant, S. , and Fitzgibbons, P. J. (1999). “Profile of auditory temporal processing in older listeners,” J. Speech Lang. Hear. Res. 42, 300–311.
15.Grose, J. H. , Hall III, J. W. , and Buss, E. (2001). “Gap duration discrimination in listeners with cochlear hearing loss: effects of gap and marker duration, frequency separation, and mode of presentation,” J. Assoc. Res. Otolaryngol. 2, 388–398.
16.Herdman, A. T. , Lins, O. , Van Roon, P. , Stapells, D. R. , Scherg, M. , and Picton, T. W. (2002). “Intracerebral sources of human auditory steady-state responses,” Brain Topogr 15, 69–86.
17.John, M. S. , and Picton, T. W. (2000). “MASTER: A Windows program for recording multiple auditory steady-state responses,” Comput. Methods Programs Biomed. 61, 125–150.
18.John, M. S. , Dimitrijevic, A. , and Picton, T. W. (2003). “Efficient stimuli for evoking auditory steady-state responses,” Ear Hear. 24, 406–423.
19.Linden, R. D. , Campbell, K. B. , Hamel, G. , and Picton, T. W. (1985). “Human auditory steady state evoked potentials during sleep,” Ear Hear. 6, 167–174.
20.Moore, B. C. (1995). “Effects of cochlear damage on temporal resolution and temporal integration,” in Perceptual Consequences of Cochlear Damage, edited by B. C. Moore (Oxford University Press, Oxford), pp. 88–108.
21.Muchnik, C. , Katz-Putter, H. , Rubinstein, M. , and Hildesheimer, M. (1993). “Normative data for 40-Hz event-related potentials to 500-Hz tonal stimuli in young and elderly subjects,” Audiology 32, 27–35.
22.Norcia, A. M. , Tyler, C. W. , Hamer, R. D. , and Wesemann, W. (1989). “Measurement of spatial contrast sensitivity with the swept contrast VEP,” Vision Res. 29, 627–637.
23.Phillips, D. P. , Taylor, T. L. , Hall, S. E. , Carr, M. M. , and Mossop, J. E. (1997). “Detection of silent intervals between noises activating different perceptual channels: Some properties of central auditory gap detection,” J. Acoust. Soc. Am. 101, 3694–3705.
24.Picton, T. W. , Dimitrijevic, A. , John, M. S. , and Van Roon, P. (2001). “The use of phase in the detection of auditory steady-state responses,” Clin. Neurophysiol. 112, 1698–1711.
25.Picton, T. W. , John, M. S. , Dimitrijevic, A. , and Purcell, D. (2003a). “Human auditory steady-state responses,” Int. J. Audiol. 42, 177–219.
26.Picton, T. W. , John, M. S. , Purcell, D. W. , and Plourde, G. (2003b). “Human auditory steady-state responses: The effects of recording technique and state of arousal,” Anesth. Analg. (Baltimore) 97, 1396–1402.
27.Picton, T. W. , Hink, R. F. , Perez-Abalo, M. , Linden, R. D. , and Wiens, A. S. (1984). “Evoked potentials: How now?,” Electrophysiol. Technol. 10, 177–221.
28.Plourde, G. , and Picton, T. W. (1990). “Human auditory steady-state response during general anesthesia,” Anesth. Analg. (Baltimore) 71, 460–468.
29.Rappaport, J. M. , Gulliver, J. M. , Phillips, D. P. , Van Dorpe, R. A. , Maxner, C. E. , and Bhan, V. (1994). “Auditory temporal resolution in multiple sclerosis,” J. Otolaryngol. 23, 307–324.
30.Rees, A. , Green, G. G. , and Kay, R. H. (1986). “Steady-state evoked responses to sinusoidally amplitude-modulated sounds recorded in man,” Hear. Res. 23, 123–133.
31.Regan, D. (1966). “Some characteristics of average steady-state and transient responses evoked by modulated light,” Electroencephalogr. Clin. Neurophysiol. 20, 238–248.
32.Regan, D. (1989). Human Brain Electrophysiology: Evoked Potentials and Evoked Magnetic Fields in Science and Medicine (Elsevier Science, New York), pp. 70–98, 112–123, 273–275.
33.Rodriguez, R. , Picton, T. , Linden, D. , Hamel, G. , and Laframboise, G. (1986). “Human auditory steady state responses: Effects of intensity and frequency,” Ear Hear. 7, 300–313.
34.Rosen, S. (1992). “Temporal information in speech: acoustic, auditory and linguistic aspects,” Philos. Trans. R. Soc. London, Ser. B 336, 367–373.
35.Sapsford, D. J. , Pickworth, A. J. , and Jones, J. G. (1996). “A method for producing the coherent frequency: A steady-state auditory evoked response in the electroencephalogram,” Anesth. Analg. (Baltimore) 83, 1273–1278.
36.Schneider, B. (1997). “Psychoacoustics and aging: Implications for everyday listening,” J. Speech-Lang. Pathol. Audiol. 21, 111–124.
37.Schneider, B. A. , and Hamstra, S. J. (1999). “Gap detection thresholds as a function of tonal duration for younger and older listeners,” J. Acoust. Soc. Am. 106, 371–380.
38.Schneider, B. A. , Daneman, M. , and Pichora-Fuller, M. K. (2002). “Listening in aging adults: From discourse comprehension to psychoacoustics,” Can. J. Exp. Psychol. 56, 139–152.
39.Schneider, B. , Speranza, F. , and Pichora-Fuller, M. K. (1998). “Age-related changes in temporal resolution: Envelope and intensity effects,” Can. J. Exp. Psychol. 52, 184–191.
40.Shailer, M. J. , and Moore, B. C. (1983). “Gap detection as a function of frequency, bandwidth, and level,” J. Acoust. Soc. Am. 74, 467–473.
41.Shannon, R. V. , Zeng, F. G. , Kamath, V. , Wygonski, J. , and Ekelid, M. (1995). “Speech recognition with primarily temporal cues,” Science 270, 303–304.
42.Snell, K. B. , and Frisina, D. R. (2000). “Relationships among age-related differences in gap detection and word recognition,” J. Acoust. Soc. Am. 107, 1615–1626.
43.Snell, K. B. , Mapes, F. M. , Hickman, E. D. , and Frisina, D. R. (2002). “Word recognition in competing babble and the effects of age, temporal processing, and absolute sensitivity,” J. Acoust. Soc. Am. 112, 720–727.
44.Stapells, D. R. , Linden, D. , Suffield, J. B. , Hamel, G. , and Picton, T. W. (1984). “Human auditory steady-state potentials,” Ear Hear. 5, 105–113.
45.Taylor, M. M. , and Creelman, C. D. (1967). “PEST: Efficient estimates on probability functions,” J. Acoust. Soc. Am. 41, 782–787.
46.Van Tasell, D. J. , Soli, S. D. , Kirby, V. M. , and Widin, G. P. (1987). “Speech waveform envelope cues for consonant recognition,” J. Acoust. Soc. Am. 82, 1152–1161.
47.Viemeister, N. F. (1979). “Temporal modulation transfer functions based upon modulation thresholds,” J. Acoust. Soc. Am. 66, 1364–1380.
48.Viemeister, N. F., and Plack, C. J. (1993). “Time analysis,” in Human Psychophysics, edited by W. A. Yost, A. N. Popper, and R. R. Fay (Springer, New York), pp. 116–154.
49.Werner, L. A. , Folsom, R. C. , Mancl, L. R. , and Syapin, C. L. (2001). “Human auditory brainstem response to temporal gaps in noise,” J. Speech Lang. Hear. Res. 44, 737–750.
50.Zeng, F. G. , Oba, S. , Garde, S. , Sininger, Y. , and Starr, A. (1999). “Temporal and speech processing deficits in auditory neuropathy,” NeuroReport 10, 3429–3435.
51.Zeng, F. G., Oba, S., Garde, S., Sininger, Y., and Starr, A. (2001). “Psychoacoustics and speech perception in auditory neuropathy,” in Auditory Neuropathy, edited by Y. Sininger and A. Starr (Singular Thomson Learning, San Diego), pp. 141–164.
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