Cortical Evoked Response to Gaps in Noise: Within-Channel and Across-Channel Conditions

Lister, Jennifer J.; Maxfield, Nathan D.; Pitt, Gabriel J.

doi:10.1097/aud.0b013e3181576cba

Cited by 43 publications

(95 citation statements)

References 64 publications

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“…The latter enhancement was further significantly stronger than the former (t 13 ϭ 2.9, p Ͻ 0.02). The timing of these enhancements was consistent with that reported by EEG studies on gap detection in noise (Michalewski et al, 2005;Pratt et al, 2005;Lister et al, 2007), tones (Heinrich et al, 2004), or noiseinterrupted tones (Riecke et al, 2009b). They further matched previously observed increases in 4 Hz power to sound onsets and offsets (Makeig, 1993;Riecke et al, 2009b).…”

Section: Neural On/off Responses To the Missing Vowel Portionsupporting

confidence: 90%

Hearing an Illusory Vowel in Noise: Suppression of Auditory Cortical Activity

Riecke¹,

Vanbussel

Hausfeld

et al. 2012

Journal of Neuroscience

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Human hearing is constructive. For example, when a voice is partially replaced by an extraneous sound (e.g., on the telephone due to a transmission problem), the auditory system may restore the missing portion so that the voice can be perceived as continuous (Miller and Licklider, 1950; for review, see Bregman, 1990; Warren, 1999). The neural mechanisms underlying this continuity illusion have been studied mostly with schematic stimuli (e.g., simple tones) and are still a matter of debate (for review, see Petkov and Sutter, 2011). The goal of the present study was to elucidate how these mechanisms operate under more natural conditions. Using psychophysics and electroencephalography (EEG), we assessed simultaneously the perceived continuity of a human vowel sound through interrupting noise and the concurrent neural activity. We found that vowel continuity illusions were accompanied by a suppression of the 4 Hz EEG power in auditory cortex (AC) that was evoked by the vowel interruption. This suppression was stronger than the suppression accompanying continuity illusions of a simple tone. Finally, continuity perception and 4 Hz power depended on the intactness of the sound that preceded the vowel (i.e., the auditory context). These findings show that a natural sound may be restored during noise due to the suppression of 4 Hz AC activity evoked early during the noise. This mechanism may attenuate sudden pitch changes, adapt the resistance of the auditory system to extraneous sounds across auditory scenes, and provide a useful model for assisted hearing devices.

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Section: Neural On/off Responses To the Missing Vowel Portionsupporting

confidence: 90%

Hearing an Illusory Vowel in Noise: Suppression of Auditory Cortical Activity

Riecke¹,

Vanbussel

Hausfeld

et al. 2012

Journal of Neuroscience

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“…In terms of the effect of gap duration on ACC latency, the findings have not been consistent. Whereas some researchers found a significant effect (Pratt et al, 2005; Lister et al, 2007), other researchers reported no effect at all (Michalewski et al, 2005). In addition, the effect of intensity change on ACC latency is still unknown.…”

Section: Introductionmentioning

confidence: 94%

“…Jones and colleagues (Jones et al, 1998; Jones and Perez, 2001, 2002) reported that the ACC response could also be recorded in response to changes in pitch and/or timbre of synthesized music. In addition, several studies have shown that the ACC response can be recorded using ongoing stimuli that contain silent gaps of various durations (Michalewski et al, 2005; Pratt et al, 2005, 2007; Lister et al, 2007; Atcherson et al, 2009). Results of these studies showed that the ACC amplitude increased with increasing magnitude of acoustic changes in intensity (Martin and Boothroyd, 2000; Harris et al, 2007; Dimitrijevic et al, 2009, 2011), spectrum (Harris et al, 2008; Dimitrijevic et al, 2009, 2011), and gap duration (Michalewski et al, 2005).…”

Section: Introductionmentioning

confidence: 99%

Auditory discrimination: The relationship between psychophysical and electrophysiological measures

Grose

Buchman

2012

International Journal of Audiology

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Objectives This study aimed to 1) investigate the relationship between the acoustic change complex (ACC) and perceptual measures of frequency and intensity discrimination, and gap detection; and 2) examine the effects of acoustic change on the amplitudes and latencies of the ACC. Design Psychophysical thresholds for frequency and intensity discrimination and gap detection, as well as ACCs elicited by stimuli containing increments in frequency, or intensity or gaps, were recorded from the same group of subjects. The magnitude of the acoustic change was systematically varied for the ACC recording. Study Sample Twenty-six adults with normal hearing ranging in age between 19 and 39 years. Results Electrophysiological and psychophysical measures for frequency and intensity discrimination were significantly correlated. Electrophysiological thresholds were comparable to psychophysical thresholds for intensity discrimination but were higher than psychophysical thresholds for gap detection and frequency discrimination. Increasing magnitude of acoustic change increased the ACC amplitude but did not show consistent effects across acoustic dimensions for ACC latency. Conclusions The ACC can be used as an objective index of auditory discrimination in frequency and intensity. The ACC amplitude is a better indicator for auditory processing than the ACC latency.

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“…For example, a repeating sound at a random frequency and a repeating three-sound pattern appearing after random frequency sounds have been found to be evoking magnetic 100 (M100) responses [electroencephalography (EEG) N1 response] in the root mean square amplitude waveform of magnetoencephalography recordings [5,6] . In fact, cortical implications of auditory processes, ranging from the detection of sound onset to the detection of frequency changes as well as the detection of embedded gaps in continuous noise, are reflected on N1 responses, the magnetic counterpart of which is the M100 response [7][8][9][10][11][12] .…”

Section: Introductionmentioning

confidence: 99%

Comparison of Regularity Detection between Individuals with and without Speech-in-Noise Problems using Electrophysiological Methods

Yaralı

Yağcıoğlu²,

Güven³

et al. 2016

Int Adv Otol

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OBJECTIVE:To analyze the cortical representations of auditory regularities and the relation between these representations and speech-in-noise (SIN) abilities and to compare two groups of participants with different SIN abilities on these cortical measures. MATERIALS and METHODS:In total, 22 participants aged 20-40 years with normal hearing and without noise exposure, brain stem level-processing issues, neurological/psychiatric issues, or related medication were presented with three different stimuli resembling auditory regularities appearing after random sounds as well as a random series of sounds. Participants received a total of 480 stimuli in passive and active phases each (in which they actively detected regularities). Evoked responses were recorded via 20-channel standard electroencephalography (EEG) cap. RESULTS:The groups were not significantly different in terms of evoked potential parameters. A significant negative correlation was observed between amplitudes of responses evoked by decreasing the frequency regularity in the active phase and SIN scores. Response parameters were significantly different between the stimuli. Active phase latencies were shorter and amplitudes were higher than passive phase ones, except for two stimuli. CONCLUSION:Cortical representations of decreasing frequency regularity are promising for revealing the link between SIN and representations of regularity detection. This paradigm is suggested to applicable to individuals with clinical-level SIN problems [hearing aid (HA) and cochlear implant (CI) users, normal-hearing individuals, children with learning problems, children with dyslexia, and others] to reveal which process of SIN mechanism is defective; this is a complicated process with many sub-mechanisms. These results may be utilized in designing CI and HA algorithms (for more robust representations of auditory regularities) and rehabilitation programs.

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Cortical Evoked Response to Gaps in Noise: Within-Channel and Across-Channel Conditions

Cited by 43 publications

References 64 publications

Hearing an Illusory Vowel in Noise: Suppression of Auditory Cortical Activity

Hearing an Illusory Vowel in Noise: Suppression of Auditory Cortical Activity

Auditory discrimination: The relationship between psychophysical and electrophysiological measures

Comparison of Regularity Detection between Individuals with and without Speech-in-Noise Problems using Electrophysiological Methods

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