Neural coding of the sound envelope is changed in the inferior colliculus immediately following acoustic trauma

Sensorineural hearing loss is often accompanied by difficulties with understanding speech in fluctuating backgrounds, suggesting that neural coding of complex sound features, such as the sound envelope, is impaired. Here, we studied how temporal and rate coding of the envelope is affected in the inf...

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Published inThe European journal of neuroscience Vol. 49; no. 10; pp. 1220 - 1232
Main Authors Heeringa, Amarins N., van Dijk, Pim
Format Journal Article
LanguageEnglish
Published France Wiley Subscription Services, Inc 01.05.2019
Subjects
Acoustic Stimulation
Acoustics
amplitude modulation
Animals
Auditory Perception - physiology
Auditory system
Evoked Potentials, Auditory, Brain Stem
guinea pig
Guinea Pigs
Hearing loss
Hearing Loss, Noise-Induced - physiopathology
Hearing protection
Inferior Colliculi - physiology
Inferior colliculus
Information processing
Male
Neural coding
Neurons - physiology
Noise
noise‐induced hearing loss
rate coding
Signal Processing, Computer-Assisted
Speech
temporal coding
Temporal variations
Trauma
guinea pig
amplitude modulation
noise-induced hearing loss
temporal coding
rate coding
Online AccessGet full text
ISSN0953-816X
1460-9568
1460-9568
DOI10.1111/ejn.14299

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Abstract Sensorineural hearing loss is often accompanied by difficulties with understanding speech in fluctuating backgrounds, suggesting that neural coding of complex sound features, such as the sound envelope, is impaired. Here, we studied how temporal and rate coding of the envelope is affected in the inferior colliculus immediately after acoustic trauma. Neural activity in response to amplitude‐modulated noise was recorded from the inferior colliculus of the guinea pig, before and immediately after a 1‐hr 11‐kHz acoustic trauma. Units with a characteristic frequency (CF) below the trauma frequency (<11 kHz) showed increased response gains, a measure for temporal coding of the sound envelope, especially at low modulation frequencies (≤128 Hz). Units with a CF > 11 kHz, which had large acoustic trauma‐induced threshold shifts, had decreased response gains to amplitude‐modulated noise. Shapes of temporal modulation transfer functions shifted toward a higher proportion of low‐pass shapes in low‐CF units, and to less band‐pass shapes in high‐CF units. Furthermore, driven firing rates decreased, especially at high modulation frequencies for high‐CF units. The observed changes occurred immediately following trauma and were thus a result of the immediate trauma‐induced damage to the auditory system. If also present in human subjects, reduced response gains in high‐frequency units could disrupt coding of consonants and consequently impair speech understanding in noisy environments. Moreover, the enhanced temporal coding by low‐CF units of the low modulation frequencies could overly amplify responses to low‐frequency noise, further deteriorating listening in noise. We quantified the effects of acute acoustic trauma on encoding of amplitude modulations in the guinea pig inferior colliculus. Recording sites tuned below the exposure frequency showed enhanced temporal coding of amplitude modulations, whereas higher frequency sites showed diminished temporal coding. Temporal modulation transfer functions became more low‐pass shaped following acoustic trauma.
AbstractList Sensorineural hearing loss is often accompanied by difficulties with understanding speech in fluctuating backgrounds, suggesting that neural coding of complex sound features, such as the sound envelope, is impaired. Here, we studied how temporal and rate coding of the envelope is affected in the inferior colliculus immediately after acoustic trauma. Neural activity in response to amplitude‐modulated noise was recorded from the inferior colliculus of the guinea pig, before and immediately after a 1‐hr 11‐kHz acoustic trauma. Units with a characteristic frequency (CF) below the trauma frequency (<11 kHz) showed increased response gains, a measure for temporal coding of the sound envelope, especially at low modulation frequencies (≤128 Hz). Units with a CF > 11 kHz, which had large acoustic trauma‐induced threshold shifts, had decreased response gains to amplitude‐modulated noise. Shapes of temporal modulation transfer functions shifted toward a higher proportion of low‐pass shapes in low‐CF units, and to less band‐pass shapes in high‐CF units. Furthermore, driven firing rates decreased, especially at high modulation frequencies for high‐CF units. The observed changes occurred immediately following trauma and were thus a result of the immediate trauma‐induced damage to the auditory system. If also present in human subjects, reduced response gains in high‐frequency units could disrupt coding of consonants and consequently impair speech understanding in noisy environments. Moreover, the enhanced temporal coding by low‐CF units of the low modulation frequencies could overly amplify responses to low‐frequency noise, further deteriorating listening in noise.
Sensorineural hearing loss is often accompanied by difficulties with understanding speech in fluctuating backgrounds, suggesting that neural coding of complex sound features, such as the sound envelope, is impaired. Here, we studied how temporal and rate coding of the envelope is affected in the inferior colliculus immediately after acoustic trauma. Neural activity in response to amplitude-modulated noise was recorded from the inferior colliculus of the guinea pig, before and immediately after a 1-hr 11-kHz acoustic trauma. Units with a characteristic frequency (CF) below the trauma frequency (<11 kHz) showed increased response gains, a measure for temporal coding of the sound envelope, especially at low modulation frequencies (≤128 Hz). Units with a CF > 11 kHz, which had large acoustic trauma-induced threshold shifts, had decreased response gains to amplitude-modulated noise. Shapes of temporal modulation transfer functions shifted toward a higher proportion of low-pass shapes in low-CF units, and to less band-pass shapes in high-CF units. Furthermore, driven firing rates decreased, especially at high modulation frequencies for high-CF units. The observed changes occurred immediately following trauma and were thus a result of the immediate trauma-induced damage to the auditory system. If also present in human subjects, reduced response gains in high-frequency units could disrupt coding of consonants and consequently impair speech understanding in noisy environments. Moreover, the enhanced temporal coding by low-CF units of the low modulation frequencies could overly amplify responses to low-frequency noise, further deteriorating listening in noise.
Sensorineural hearing loss is often accompanied by difficulties with understanding speech in fluctuating backgrounds, suggesting that neural coding of complex sound features, such as the sound envelope, is impaired. Here, we studied how temporal and rate coding of the envelope is affected in the inferior colliculus immediately after acoustic trauma. Neural activity in response to amplitude‐modulated noise was recorded from the inferior colliculus of the guinea pig, before and immediately after a 1‐hr 11‐ kH z acoustic trauma. Units with a characteristic frequency ( CF ) below the trauma frequency (<11 kHz) showed increased response gains, a measure for temporal coding of the sound envelope, especially at low modulation frequencies (≤128 Hz). Units with a CF  > 11 kHz, which had large acoustic trauma‐induced threshold shifts, had decreased response gains to amplitude‐modulated noise. Shapes of temporal modulation transfer functions shifted toward a higher proportion of low‐pass shapes in low‐ CF units, and to less band‐pass shapes in high‐ CF units. Furthermore, driven firing rates decreased, especially at high modulation frequencies for high‐ CF units. The observed changes occurred immediately following trauma and were thus a result of the immediate trauma‐induced damage to the auditory system. If also present in human subjects, reduced response gains in high‐frequency units could disrupt coding of consonants and consequently impair speech understanding in noisy environments. Moreover, the enhanced temporal coding by low‐ CF units of the low modulation frequencies could overly amplify responses to low‐frequency noise, further deteriorating listening in noise.
Sensorineural hearing loss is often accompanied by difficulties with understanding speech in fluctuating backgrounds, suggesting that neural coding of complex sound features, such as the sound envelope, is impaired. Here, we studied how temporal and rate coding of the envelope is affected in the inferior colliculus immediately after acoustic trauma. Neural activity in response to amplitude-modulated noise was recorded from the inferior colliculus of the guinea pig, before and immediately after a 1-hr 11-kHz acoustic trauma. Units with a characteristic frequency (CF) below the trauma frequency (<11 kHz) showed increased response gains, a measure for temporal coding of the sound envelope, especially at low modulation frequencies (≤128 Hz). Units with a CF > 11 kHz, which had large acoustic trauma-induced threshold shifts, had decreased response gains to amplitude-modulated noise. Shapes of temporal modulation transfer functions shifted toward a higher proportion of low-pass shapes in low-CF units, and to less band-pass shapes in high-CF units. Furthermore, driven firing rates decreased, especially at high modulation frequencies for high-CF units. The observed changes occurred immediately following trauma and were thus a result of the immediate trauma-induced damage to the auditory system. If also present in human subjects, reduced response gains in high-frequency units could disrupt coding of consonants and consequently impair speech understanding in noisy environments. Moreover, the enhanced temporal coding by low-CF units of the low modulation frequencies could overly amplify responses to low-frequency noise, further deteriorating listening in noise.Sensorineural hearing loss is often accompanied by difficulties with understanding speech in fluctuating backgrounds, suggesting that neural coding of complex sound features, such as the sound envelope, is impaired. Here, we studied how temporal and rate coding of the envelope is affected in the inferior colliculus immediately after acoustic trauma. Neural activity in response to amplitude-modulated noise was recorded from the inferior colliculus of the guinea pig, before and immediately after a 1-hr 11-kHz acoustic trauma. Units with a characteristic frequency (CF) below the trauma frequency (<11 kHz) showed increased response gains, a measure for temporal coding of the sound envelope, especially at low modulation frequencies (≤128 Hz). Units with a CF > 11 kHz, which had large acoustic trauma-induced threshold shifts, had decreased response gains to amplitude-modulated noise. Shapes of temporal modulation transfer functions shifted toward a higher proportion of low-pass shapes in low-CF units, and to less band-pass shapes in high-CF units. Furthermore, driven firing rates decreased, especially at high modulation frequencies for high-CF units. The observed changes occurred immediately following trauma and were thus a result of the immediate trauma-induced damage to the auditory system. If also present in human subjects, reduced response gains in high-frequency units could disrupt coding of consonants and consequently impair speech understanding in noisy environments. Moreover, the enhanced temporal coding by low-CF units of the low modulation frequencies could overly amplify responses to low-frequency noise, further deteriorating listening in noise.
Sensorineural hearing loss is often accompanied by difficulties with understanding speech in fluctuating backgrounds, suggesting that neural coding of complex sound features, such as the sound envelope, is impaired. Here, we studied how temporal and rate coding of the envelope is affected in the inferior colliculus immediately after acoustic trauma. Neural activity in response to amplitude‐modulated noise was recorded from the inferior colliculus of the guinea pig, before and immediately after a 1‐hr 11‐kHz acoustic trauma. Units with a characteristic frequency (CF) below the trauma frequency (<11 kHz) showed increased response gains, a measure for temporal coding of the sound envelope, especially at low modulation frequencies (≤128 Hz). Units with a CF > 11 kHz, which had large acoustic trauma‐induced threshold shifts, had decreased response gains to amplitude‐modulated noise. Shapes of temporal modulation transfer functions shifted toward a higher proportion of low‐pass shapes in low‐CF units, and to less band‐pass shapes in high‐CF units. Furthermore, driven firing rates decreased, especially at high modulation frequencies for high‐CF units. The observed changes occurred immediately following trauma and were thus a result of the immediate trauma‐induced damage to the auditory system. If also present in human subjects, reduced response gains in high‐frequency units could disrupt coding of consonants and consequently impair speech understanding in noisy environments. Moreover, the enhanced temporal coding by low‐CF units of the low modulation frequencies could overly amplify responses to low‐frequency noise, further deteriorating listening in noise. We quantified the effects of acute acoustic trauma on encoding of amplitude modulations in the guinea pig inferior colliculus. Recording sites tuned below the exposure frequency showed enhanced temporal coding of amplitude modulations, whereas higher frequency sites showed diminished temporal coding. Temporal modulation transfer functions became more low‐pass shaped following acoustic trauma.
Author Heeringa, Amarins N.
van Dijk, Pim
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noise-induced hearing loss
temporal coding
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Snippet Sensorineural hearing loss is often accompanied by difficulties with understanding speech in fluctuating backgrounds, suggesting that neural coding of complex...
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SubjectTerms Acoustic Stimulation
Acoustics
amplitude modulation
Animals
Auditory Perception - physiology
Auditory system
Evoked Potentials, Auditory, Brain Stem
guinea pig
Guinea Pigs
Hearing loss
Hearing Loss, Noise-Induced - physiopathology
Hearing protection
Inferior Colliculi - physiology
Inferior colliculus
Information processing
Male
Neural coding
Neurons - physiology
Noise
noise‐induced hearing loss
rate coding
Signal Processing, Computer-Assisted
Speech
temporal coding
Temporal variations
Trauma
Title Neural coding of the sound envelope is changed in the inferior colliculus immediately following acoustic trauma
URI https://onlinelibrary.wiley.com/doi/abs/10.1111%2Fejn.14299
https://www.ncbi.nlm.nih.gov/pubmed/30549334
https://www.proquest.com/docview/2237805538
https://www.proquest.com/docview/2157654710
Volume 49
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