Aging Affects Adaptation to Sound-Level Statistics in Human Auditory Cortex

Abstract: Optimal perception requires efficient and adaptive neural processing of sensory input. Neurons in nonhuman mammals adapt to the statistical properties of acoustic feature distributions such that they become sensitive to sounds that are most likely to occur in the environment. However, whether human auditory responses adapt to stimulus statistical distributions and how aging affects adaptation to stimulus statistics is unknown. We used MEG to study how exposure to different distributions of sound levels affects… Show more

“…Discrimination performance was sensitive to the context's modal level. However, inconsistent with statistical adaptation measured neurophysiologically ( Figure 1) 10,11,17,18,21 , sound-level discrimination was better for low-intensity compared to higher-intensity target sounds in the high-modal context 24 . Neurophysiological work, in contrast, suggests that neurons are not very sensitive to low-intensity sounds when the ambient sound level is high ( Figure 1A).…”

“…The main analyses focused on neural and behavioral responses to noise bursts (targets) for which the sound level, and the sound level of the directly preceding noise, were identical across the two statistical contexts (black dots in Figure 2, middle/right). This allowed us to investigate the effects of longer-term sound-level statistics on neural responses and perception 21 .…”

“…Achieving a wide perceptual range with a limited neuronal range is thought to be accomplished by a dynamic adjustment of the response range (input-output function) of neurons to sound-level statistics in the environment ( Figure 1A) 10,11 . This process -called adaptation to stimulus statistics, dynamic range adaptation, or gain control 1,[12][13][14][15][16] -involves shifting the response range of neurons depending on the mean or modal sound level in an acoustic environment 10,11,[17][18][19][20][21][22] . When ambient sound levels are low, neurons are more sensitive and more responsive, but saturate for moderate-to highlevel sounds, compared to when ambient sound levels are moderate to high (red and teal lines in Figure 1A, respectively).…”

“…Figure 1: Schematic depiction of neural adaptation to sound-level statistics. Adopted from empirical data 10,11,21 . A: Predicted neural responses as a function of sound level for two sound-level contexts with different modal sound levels (low vs. high; inset).…”

“…Most research on adaptation of neural activity to sound-level statistics has been conducted using neurophysiological techniques in non-human mammals 10,11,13,[17][18][19][20]23 . We have recently demonstrated using magnetoencephalography that neural activity in human auditory cortex adapts to sound-level statistics (i.e., to the modal sound-level) 21 . However, whether such adaptive changes confer benefit to perceptual sensitivity is less clear.…”

Neural Responses and Perceptual Sensitivity to Sound Depend on Sound-Level Statistics

“…Discrimination performance was sensitive to the context's modal level. However, inconsistent with statistical adaptation measured neurophysiologically ( Figure 1) 10,11,17,18,21 , sound-level discrimination was better for low-intensity compared to higher-intensity target sounds in the high-modal context 24 . Neurophysiological work, in contrast, suggests that neurons are not very sensitive to low-intensity sounds when the ambient sound level is high ( Figure 1A).…”

“…The main analyses focused on neural and behavioral responses to noise bursts (targets) for which the sound level, and the sound level of the directly preceding noise, were identical across the two statistical contexts (black dots in Figure 2, middle/right). This allowed us to investigate the effects of longer-term sound-level statistics on neural responses and perception 21 .…”

“…Achieving a wide perceptual range with a limited neuronal range is thought to be accomplished by a dynamic adjustment of the response range (input-output function) of neurons to sound-level statistics in the environment ( Figure 1A) 10,11 . This process -called adaptation to stimulus statistics, dynamic range adaptation, or gain control 1,[12][13][14][15][16] -involves shifting the response range of neurons depending on the mean or modal sound level in an acoustic environment 10,11,[17][18][19][20][21][22] . When ambient sound levels are low, neurons are more sensitive and more responsive, but saturate for moderate-to highlevel sounds, compared to when ambient sound levels are moderate to high (red and teal lines in Figure 1A, respectively).…”

“…Figure 1: Schematic depiction of neural adaptation to sound-level statistics. Adopted from empirical data 10,11,21 . A: Predicted neural responses as a function of sound level for two sound-level contexts with different modal sound levels (low vs. high; inset).…”

“…Most research on adaptation of neural activity to sound-level statistics has been conducted using neurophysiological techniques in non-human mammals 10,11,13,[17][18][19][20]23 . We have recently demonstrated using magnetoencephalography that neural activity in human auditory cortex adapts to sound-level statistics (i.e., to the modal sound-level) 21 . However, whether such adaptive changes confer benefit to perceptual sensitivity is less clear.…”

Neural Responses and Perceptual Sensitivity to Sound Depend on Sound-Level Statistics

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