Sensorineural hearing loss degrades behavioral and physiological measures of human spatial selective auditory attention

Significance Listeners with hearing loss have trouble communicating in many social settings. In such situations, listeners with normal hearing suppress the neural representation of competing sounds, a process known as auditory selective attention. We compared hearing-impaired (HI) and normal-hearing (NH) listeners on a spatial selective attention task while measuring neural responses using electroencephalography. Compared with NH listeners, HI listeners have poorer sensitivity to spatial cues, perform more poorly on the selective attention task, and show weaker neural suppression of competing sounds. Moreover, these different measures are correlated both for HI and for NH listeners. These results suggest that poor spatial acuity produces problems with selective attention. These findings have implications both for basic science and for development of next-generation hearing aids. Listeners with sensorineural hearing loss often have trouble understanding speech amid other voices. While poor spatial hearing is often implicated, direct evidence is weak; moreover, studies suggest that reduced audibility and degraded spectrotemporal coding may explain such problems. We hypothesized that poor spatial acuity leads to difficulty deploying selective attention, which normally filters out distracting sounds. In listeners with normal hearing, selective attention causes changes in the neural responses evoked by competing sounds, which can be used to quantify the effectiveness of attentional control. Here, we used behavior and electroencephalography to explore whether control of selective auditory attention is degraded in hearing-impaired (HI) listeners. Normal-hearing (NH) and HI listeners identified a simple melody presented simultaneously with two competing melodies, each simulated from different lateral angles. We quantified performance and attentional modulation of cortical responses evoked by these competing streams. Compared with NH listeners, HI listeners had poorer sensitivity to spatial cues, performed more poorly on the selective attention task, and showed less robust attentional modulation of cortical responses. Moreover, across NH and HI individuals, these measures were correlated. While both groups showed cortical suppression of distracting streams, this modulation was weaker in HI listeners, especially when attending to a target at midline, surrounded by competing streams. These findings suggest that hearing loss interferes with the ability to filter out sound sources based on location, contributing to communication difficulties in social situations. These findings also have implications for technologies aiming to use neural signals to guide hearing aid processing.

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