Summary: Humans have vestigial ear muscles that once helped our ancestors focus on sounds. New research shows these muscles still activate when we strain to hear in noisy environments. Scientists used electromyography to measure auricular muscle activity in people listening to an audiobook with distracting background noise.
The superior auricular muscle responded most when participants struggled to follow speech. Although these tiny muscle movements likely don’t improve hearing, they may provide an objective measure of listening effort. Further research could help understand their role in individuals with hearing impairments.
Key Facts:
- Vestigial Function: Human ear muscles, once used to localize sounds, still activate during intense listening tasks.
- Listening Effort: The superior auricular muscle responds more when background noise makes speech harder to follow.
- Future Research: Understanding these muscles may improve hearing assessments and aid those with hearing impairments.
Source: Frontiers
If you can wiggle your ears, you can use muscles that helped our distant ancestors listen closely. These auricular muscles helped change the shape of the pinna, or the shell of the ear, funneling sound to the eardrums.
Millions of years ago, our ancestors stopped using them, so humans’ auricular muscles are only vestigial. But now scientists examining the function of these muscles have discovered that they activate when we’re trying to listen to competing sounds.
“There are three large muscles which connect the auricle to the skull and scalp and are important for ear wiggling,” explained Andreas Schröer of Saarland University, first author of the study in Frontiers in Neuroscience.
“These muscles, particularly the superior auricular muscle, exhibit increased activity during effortful listening tasks. This suggests that these muscles are engaged not merely as a reflex but potentially as part of an attentional effort mechanism, especially in challenging auditory environments.”
Straining your ears
It’s difficult to test how hard someone is listening without self-reported measures. But electromyography, which measures electrical activity in a muscle, can help identify activity in the auricular muscles linked to listening closely.
Similar research has already shown that the largest muscles, posterior and superior auricular muscles, react during attentive listening. Because they pull the ears up and back, they are considered likely to have been involved in moving the pinna to capture sounds.
“The exact reason these became vestigial is difficult to tell, as our ancestors lost this ability about 25 million years ago,” Schröer said.
“One possible explanation could be that the evolutionary pressure to move the ears ceased because we became much more proficient with our visual and vocal systems.”
To test whether these muscles are more active during more difficult listening tasks, the scientists recruited 20 people without hearing problems. They applied electrodes to participants’ auricular muscles and then played them an audiobook and distracting podcasts from speakers in front of or behind them.
Each participant underwent 12 five-minute trials, covering three different levels of difficulty.
On easy mode, the podcast was quieter than the audiobook, and the speaker’s voice was a stronger contrast to the audiobook. To create two more difficult modes, the scientists added a podcast that sounded more like the audiobook and made the distractors louder.
However, the researchers were careful to make even the most difficult condition achievable: if the participants gave up, no physiological effort would register.
Then, the scientists asked the participants to rate their effort levels and to estimate how often they lost the thread of the audiobook in each trial. They also quizzed the participants on the audiobook’s content.
Hearsay
The scientists found that the two auricular muscles reacted differently to the different conditions. The posterior auricular muscles reacted to changes in direction, while the superior auricular muscles reacted to the difficulty level of the task.
Participants’ self-reported measures of effort and how often they lost track of the audiobook rose in line with the difficulty of the task, and the accuracy of their responses to questions about the audiobook dropped noticeably between the medium and the difficult mode.
This correlated with the superior auricular muscles’ activity levels: they didn’t activate more during the medium mode than during the easy mode, but were very active during the difficult mode.
This suggests that the activity of the superior auricular muscles could provide an objective measure of listening effort, although it’s unclear if the muscle activity helps people hear.
“The ear movements that could be generated by the signals we have recorded are so minuscule that there is probably no perceivable benefit,” said Schröer.
“However, the auricle itself does contribute to our ability to localize sounds. So, our auriculomotor system probably tries its best after being vestigial for 25 million years, but does not achieve much.”
The scientists pointed out that more work will be necessary to confirm these results and develop practical applications. Like many hearing studies, their sample was relatively small and composed of young people without hearing problems. Larger, more diverse participant groups, in more realistic conditions, are needed.
“Investigating the possible effects of muscle strain itself or the ear’s miniscule movements on the transmission of sound is something we want to do in the future,” said Schröer.
“The effect of these factors in people with hearing impairments would also be interesting to investigate.”
About this auditory neuroscience research news
Author: Angharad Brewer Gillham
Source: Frontiers
Contact: Angharad Brewer Gillham – Frontiers
Image: The image is credited to Neuroscience News
Original Research: Open access.
“Electromyographic Correlates of Effortful Listening in the Vestigial Auriculomotor System” by Andreas Schröer et al. Frontiers in Neuroscience
Abstract
Electromyographic Correlates of Effortful Listening in the Vestigial Auriculomotor System
Recently, electromyographic (EMG) signals of auricular muscles have been shown to be an indicator of spatial auditory attention in humans, based on a vestigial pinna-orienting system.
Because spatial auditory attention in a competing speaker task is closely related to the more generalized concept of attentional effort in listening, the current study investigated the possibility that the EMG activity of auricular muscles could also reflect correlates of effortful listening in general.
Twenty participants were recruited. EMG signals from the left and right superior and posterior auricular muscles (SAM, PAM) were recorded while participants attended a target podcast in a competing speaker paradigm.
Three different conditions, each more difficult and requiring a higher amount of effortful listening, were generated by varying the number and pitch of distractor streams, as well as the signal-to-noise ratio. All audio streams were either presented from a loudspeaker placed in front of the participants (0°), or in the back (180°).
Overall, averaged PAM activity was not affected by different levels of effortful listening, but was significantly larger when stimuli were presented from the back, as opposed to the front.
Averaged SAM activity, however, was significantly larger in the most difficult condition, which required the largest amount of effort, compared to the easier conditions, but was not affected by stimulus direction.
We interpret the increased SAM activity to be the response of the vestigial pinna–orienting system to an effortful stream segregation task.
