Summary:
A new study from the University of Michigan and the University of Rochester, published in PLoS Biology, finds that humans’ ability to focus on a single voice in noisy environments—known as selective attention—originates in the brain’s cortex, not in subcortical structures like the brainstem or auditory nerve.
Key Takeaways:
- Researchers found no measurable subcortical processing differences when participants focused on one voice over another, suggesting selective attention operates mainly in the cortex.
- The study used realistic listening tasks with overlapping audiobook narrations, improving on prior research that relied on artificial sounds.
- While current methods detected no subcortical effects, scientists note future advances in technology may reveal subtle neural mechanisms that current tools cannot yet observe.
Research led by the University of Michigan’s Kresge Hearing Research Institute and the University of Rochester which was recently published in the journal PLOS Biology illuminates the mechanisms through which humans can pick out and focus on single sounds in noisy environments.
Previous studies had established that this ability to filter sound, called “selective attention,” involved the auditory cortex of the brain.
Evidence had been inconclusive, however, as to whether that selective attention involved sound being processed differently at the subcortical level — i.e. in the brainstem or the auditory nerve, which receive the sound signals from the ear and process them before eventually passing them on to the cortex.
Using novel experimental techniques, researchers found no evidence of such subcortical processing.
“What we found is that the subcortical parts of the auditory system respond to speech you’re paying attention to in exactly the same way as the speech you’re ignoring,” says Ross Maddox, PhD, associate professor of otolaryngology at the University of Michigan medical school, member of the Kresge Hearing Research Institute, and senior author on the paper. “This is different from the cortex, which neurally ‘turns up the volume’ on the sound you’re focusing on.”
Most prior research into selective attention relied on artificial sounds. In this study, however, participants listened to segments from two audiobooks read by different narrators, better simulating the “cocktail party” task of focusing on a single speaker.
With responses measured from the auditory nerve, the brainstem and the cortex, subjects showed no subcortical effect when the two audiobooks were played simultaneously in both ears (diotic listening) or when the two audiobooks were played in opposite ears (dichotic listening).
Furthermore, statistical analysis suggested evidence against such subcortical effects.
A strong attention effect was measured in the cortex, replicating previous findings.
Researchers suggest that contradictory findings from one similar prior study may owe to differences in experimental design.
In that earlier research, multiple stories were spoken by each narrator, introducing a possible effect from “uncontrolled acoustic differences.”
An additional experiment detailed in this paper confirmed the possibility of that design influencing results.
Researchers emphasize, however, that the lack of evidence does not preclude the possibility that selective attention utilizes auditory nerve or brainstem in a way that cannot yet be observed.
They speculate that, for instance, certain neurons that are too few to be measured by present techniques could be involved in a related subcortical process.
“I think what we’ve shown here is that for human studies, there is no subcortical attention effect that can be measured with the tools we have available,” Maddox says. “In fact, we had to develop some new experimental methods for this study to help settle the debate. But it’s always possible that as we and other labs keep pushing on the technology front, new studies will allow us to take a more detailed look at what’s going on inside our auditory brains.”
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