{"id":1848986,"date":"2018-08-23T14:54:42","date_gmt":"2018-08-23T18:54:42","guid":{"rendered":"https:\/\/www.wdev.futurity.org\/?p=1848986"},"modified":"2018-08-24T16:21:30","modified_gmt":"2018-08-24T20:21:30","slug":"brains-hearing-interpretation-1846162","status":"publish","type":"post","link":"https:\/\/www.futurity.org\/brains-hearing-interpretation-1846162\/","title":{"rendered":"Our brains have ‘auto-correct’ to handle tricky sounds"},"content":{"rendered":"

Our brains have an “auto-correct” feature that we deploy when re-interpreting ambiguous sounds, according to new research.<\/p>\n

“What a person thinks they hear does not always match the actual signals that reach the ear…”<\/p><\/blockquote>\n

The study sheds light on how the brain uses information gathered after the detection of an initial sound to aid speech comprehension. The findings, which appear in the Journal of Neuroscience<\/em><\/a>, point to new ways we use information and context to aid in speech comprehension.<\/p>\n

“What a person thinks they hear does not always match the actual signals that reach the ear,” explains lead author Laura Gwilliams, a doctoral candidate in the psychology department at New York University and researcher at the Neuroscience of Language Lab at NYU Abu Dhabi.<\/p>\n

“This is because, our results suggest, the brain re-evaluates the interpretation of a speech sound at the moment that each subsequent speech sound is heard in order to update interpretations as necessary,” Gwilliams says.<\/p>\n

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Volunteers come to the lab for the experiment. The first step is to make a 3D digital model of their head.
(Credit: Kate Lord\/NYU)<\/figcaption><\/figure>\n

“Remarkably, our hearing can be affected by context occurring up to one second later, without the listener ever being aware of this altered perception.”<\/p>\n

“For example, an ambiguous initial sound, such as ‘b’ and ‘p,’ is heard one way or another depending on if it occurs in the word ‘parakeet’ or ‘barricade,'” adds principal investigator Alec Marantz, a professor in the linguistics and psychology departments, and co-director of the Neuroscience of Language Lab, where the researchers conducted their work.<\/p>\n

“This happens without conscious awareness of the ambiguity, even though the disambiguating information doesn’t come until the middle of the third syllable.”<\/p>\n

The researchers have created examples of these stimuli, which you can listen to here<\/a>.<\/p>\n

Context is key<\/h3>\n

It’s well known that the perception of a speech sound is determined by its surrounding context\u2014in the form of words, sentences, and other speech sounds. In many instances, this contextual information is heard later than the initial sensory input.<\/p>\n

“What is interesting is the fact that this context can occur after the sounds being interpreted and still be used to alter how the sound is perceived…”<\/p><\/blockquote>\n

This plays out in every-day life\u2014when we talk, the actual speech we produce is often ambiguous. For example, when a friend says she has a “dent” in her car, you may hear “tent.” Although this kind of ambiguity happens regularly, we, as listeners, are hardly aware of it.<\/p>\n

“This is because the brain automatically resolves the ambiguity for us\u2014it picks an interpretation and that’s what we perceive to hear,” explains Gwilliams. “The way the brain does this is by using the surrounding context to narrow down the possibilities of what the speaker may mean.”<\/p>\n

In the study, the researchers sought to understand how the brain uses this subsequent information to modify our perception of what we initially heard.<\/p>\n

Now hear this<\/h3>\n

To do this, they conducted a series of experiments in which the subjects listened to isolated syllables and similarly sounding words (e.g., barricade, parakeet). In order to gauge the subjects’ brain activity, the scientists deployed magnetoencephalography (MEG), a technique that maps neural movement by recording magnetic fields generated by the electrical currents produced by our brain.<\/p>\n

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Electromagnets are attached to the participant\u2019s head and help determine where the head is located inside the machine. (Credit: Kate Lord\/NYU)<\/figcaption><\/figure>\n

Their results yielded three primary findings:<\/p>\n