The masking of narrowband noise by broadband harmonic complex sounds and implications for the processing of speech sounds

Musical expertise has been shown to positively influence high-level speech abilities such as novel word learning. This study addresses the question whether low-level enhanced perceptual skills causally drives successful novel word learning. We used a longitudinal approach with psychoacoustic procedures to train 2 groups of nonmusicians either on pitch discrimination or on intensity discrimination, using harmonic complex sounds. After short (approximately 3 hr) psychoacoustic training, discrimination thresholds were lower on the specific feature (pitch or intensity) that was trained. Moreover, compared to the intensity group, participants trained on pitch were faster to categorize words varying in pitch. Finally, although the N400 components in both the word learning phase and in the semantic task were larger in the pitch group than in the intensity group, no between-group differences were found at the behavioral level in the semantic task. Thus, these results provide mixed evidence that enhanced perception of relevant features through a few hours of acoustic training with harmonic sounds causally impacts the categorization of speech sounds as well as novel word learning. These results are discussed within the framework of near and far transfer effects from music training to speech processing.

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Neural Correlates of Auditory Streaming of Harmonic Complex Sounds With Different Phase Relations in the Songbird Forebrain

Journal of Neurophysiology ◽

10.1152/jn.00496.2010 ◽

2011 ◽

Vol 105 (1) ◽

pp. 188-199 ◽

Cited By ~ 14

Author(s):

Naoya Itatani ◽

Georg M. Klump

Keyword(s):

Random Phase ◽

Phase Relations ◽

Stream Segregation ◽

Neural Representation ◽

Center Frequency ◽

Response Patterns ◽

Harmonic Complex ◽

Complex Sounds ◽

Temporal Cues ◽

Spectral Separation

It has been suggested that successively presented sounds that are perceived as separate auditory streams are represented by separate populations of neurons. Mostly, spectral separation in different peripheral filters has been identified as the cue for segregation. However, stream segregation based on temporal cues is also possible without spectral separation. Here we present sequences of ABA- triplet stimuli providing only temporal cues to neurons in the European starling auditory forebrain. A and B sounds (125 ms duration) were harmonic complexes (fundamentals 100, 200, or 400 Hz; center frequency and bandwidth chosen to fit the neurons' tuning characteristic) with identical amplitude spectra but different phase relations between components (cosine, alternating, or random phase) and presented at different rates. Differences in both rate responses and temporal response patterns of the neurons when stimulated with harmonic complexes with different phase relations provide first evidence for a mechanism allowing a separate neural representation of such stimuli. Recording sites responding >1 kHz showed enhanced rate and temporal differences compared with those responding at lower frequencies. These results demonstrate a neural correlate of streaming by temporal cues due to the variation of phase that shows striking parallels to observations in previous psychophysical studies.

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Cochlear Nerve and Cochlear Nucleus Responses to the Fundamental Frequency of Voiced Speech Sounds and Harmonic Complex Tones

Auditory Physiology and Perception ◽

10.1016/b978-0-08-041847-6.50032-0 ◽

1992 ◽

pp. 231-239 ◽

Cited By ~ 10

Author(s):

Alan R. Palmer ◽

Ian M. Winter

Keyword(s):

Fundamental Frequency ◽

Cochlear Nucleus ◽

Cochlear Nerve ◽

Speech Sounds ◽

Harmonic Complex ◽

Complex Tones ◽

Voiced Speech

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Harmonic template neurons in primate auditory cortex underlying complex sound processing

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1607519114 ◽

2017 ◽

Vol 114 (5) ◽

pp. E840-E848 ◽

Cited By ~ 27

Author(s):

Lei Feng ◽

Xiaoqin Wang

Keyword(s):

Auditory Cortex ◽

Common Marmoset ◽

Neural Mechanisms ◽

Sound Processing ◽

Harmonic Complex ◽

Complex Sound ◽

Complex Sounds ◽

Animal Vocalizations ◽

The Common ◽

Hearing Range

Harmonicity is a fundamental element of music, speech, and animal vocalizations. How the auditory system extracts harmonic structures embedded in complex sounds and uses them to form a coherent unitary entity is not fully understood. Despite the prevalence of sounds rich in harmonic structures in our everyday hearing environment, it has remained largely unknown what neural mechanisms are used by the primate auditory cortex to extract these biologically important acoustic structures. In this study, we discovered a unique class of harmonic template neurons in the core region of auditory cortex of a highly vocal New World primate, the common marmoset (Callithrix jacchus), across the entire hearing frequency range. Marmosets have a rich vocal repertoire and a similar hearing range to that of humans. Responses of these neurons show nonlinear facilitation to harmonic complex sounds over inharmonic sounds, selectivity for particular harmonic structures beyond two-tone combinations, and sensitivity to harmonic number and spectral regularity. Our findings suggest that the harmonic template neurons in auditory cortex may play an important role in processing sounds with harmonic structures, such as animal vocalizations, human speech, and music.

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Sensory-Cognitive Interaction in the Neural Encoding of Speech in Noise: A Review

Journal of the American Academy of Audiology ◽

10.3766/jaaa.21.9.3 ◽

2010 ◽

Vol 21 (09) ◽

pp. 575-585 ◽

Cited By ~ 41

Author(s):

Samira Anderson ◽

Nina Kraus

Keyword(s):

Older Adults ◽

Background Noise ◽

Objective Assessment ◽

Auditory Brainstem ◽

Speech Sounds ◽

Complex Sounds ◽

Speech In Noise ◽

Hearing In Noise ◽

Brainstem Response ◽

Noise Test

Background: Speech-in-noise (SIN) perception is one of the most complex tasks faced by listeners on a daily basis. Although listening in noise presents challenges for all listeners, background noise inordinately affects speech perception in older adults and in children with learning disabilities. Hearing thresholds are an important factor in SIN perception, but they are not the only factor. For successful comprehension, the listener must perceive and attend to relevant speech features, such as the pitch, timing, and timbre of the target speaker's voice. Here, we review recent studies linking SIN and brainstem processing of speech sounds. Purpose: To review recent work that has examined the ability of the auditory brainstem response to complex sounds (cABR), which reflects the nervous system's transcription of pitch, timing, and timbre, to be used as an objective neural index for hearing-in-noise abilities. Study Sample: We examined speech-evoked brainstem responses in a variety of populations, including children who are typically developing, children with language-based learning impairment, young adults, older adults, and auditory experts (i.e., musicians). Data Collection and Analysis: In a number of studies, we recorded brainstem responses in quiet and babble noise conditions to the speech syllable /da/ in all age groups, as well as in a variable condition in children in which /da/ was presented in the context of seven other speech sounds. We also measured speech-in-noise perception using the Hearing-in-Noise Test (HINT) and the Quick Speech-in-Noise Test (QuickSIN). Results: Children and adults with poor SIN perception have deficits in the subcortical spectrotemporal representation of speech, including low-frequency spectral magnitudes and the timing of transient response peaks. Furthermore, auditory expertise, as engendered by musical training, provides both behavioral and neural advantages for processing speech in noise. Conclusions: These results have implications for future assessment and management strategies for young and old populations whose primary complaint is difficulty hearing in background noise. The cABR provides a clinically applicable metric for objective assessment of individuals with SIN deficits, for determination of the biologic nature of disorders affecting SIN perception, for evaluation of appropriate hearing aid algorithms, and for monitoring the efficacy of auditory remediation and training.

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Complex pitch perception mechanisms are shared by humans and a New World monkey

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1516120113 ◽

2015 ◽

Vol 113 (3) ◽

pp. 781-786 ◽

Cited By ~ 33

Author(s):

Xindong Song ◽

Michael S. Osmanski ◽

Yueqi Guo ◽

Xiaoqin Wang

Keyword(s):

Speech Processing ◽

New World ◽

World Monkey ◽

Common Marmoset ◽

Pitch Perception ◽

Frequency Resolution ◽

Harmonic Complex ◽

Complex Sounds ◽

New World Monkey ◽

Underlying Mechanisms

The perception of the pitch of harmonic complex sounds is a crucial function of human audition, especially in music and speech processing. Whether the underlying mechanisms of pitch perception are unique to humans, however, is unknown. Based on estimates of frequency resolution at the level of the auditory periphery, psychoacoustic studies in humans have revealed several primary features of central pitch mechanisms. It has been shown that (i) pitch strength of a harmonic tone is dominated by resolved harmonics; (ii) pitch of resolved harmonics is sensitive to the quality of spectral harmonicity; and (iii) pitch of unresolved harmonics is sensitive to the salience of temporal envelope cues. Here we show, for a standard musical tuning fundamental frequency of 440 Hz, that the common marmoset (Callithrix jacchus), a New World monkey with a hearing range similar to that of humans, exhibits all of the primary features of central pitch mechanisms demonstrated in humans. Thus, marmosets and humans may share similar pitch perception mechanisms, suggesting that these mechanisms may have emerged early in primate evolution.

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Editorial Note

Journal of Speech Disorders ◽

10.1044/jshd.1101.02 ◽

1946 ◽

Vol 11 (1) ◽

pp. 2-2

Keyword(s):

Editorial Note ◽

Speech Sounds ◽

Left Hand ◽

Hand Column ◽

Right Hand ◽

Infant Speech ◽

The Right

In the article “Infant Speech Sounds and Intelligence” by Orvis C. Irwin and Han Piao Chen, in the December 1945 issue of the Journal, the paragraph which begins at the bottom of the left hand column on page 295 should have been placed immediately below the first paragraph at the top of the right hand column on page 296. To the authors we express our sincere apologies.

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Head Position Identification

Journal of Speech and Hearing Research ◽

10.1044/jshr.1003.438 ◽

1967 ◽

Vol 10 (3) ◽

pp. 438-448

Author(s):

H. N. Wright

Keyword(s):

Roc Curve ◽

Head Position ◽

Hearing Impaired ◽

Type Ii ◽

Experimental Conditions ◽

Partial Explanation ◽

Complex Sounds ◽

Binaural Cues ◽

Criterion Behavior ◽

Stimulus Degradation

A binaural recording of traffic sounds that reached an artificial head oriented in five different positions was presented to five subjects, each of whom responded under four different criteria. The results showed that it is possible to examine the ability of listeners to localize sound while listening through earphones and that the criterion adopted by an individual listener is independent of his performance. For the experimental conditions used, the Type II ROC curve generated by manipulating criterion behavior was linear and consistent with a guessing model. Further experiments involving different degrees of stimulus degradation suggested a partial explanation for this finding and illustrated the various types of monaural and binaural cues used by normal and hearing-impaired listeners to localize complex sounds.

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