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Using a cappella to explain speech and music specialization

Figure shows original song (bottom left) and its spectrogram (above it, in blue). This spectrogram can be decomposed according to the amount of energy contained in spectral and temporal modulation rates (central panel). Auditory cortex on the right and left sides of the brain (right side of figure) decode melody and speech, respectively, because the melody depends more on spectral modulations and the speech depends more on temporal modulations.
Published: 27 February 2020

Study suggests humans have developed complementary neural systems in each hemisphere for auditory stimuli

Speech and music are two fundamentally human activities that are decoded in different brain hemispheres. A new study used a unique approach to reveal why this specialization exists.

Researchers at The Neuro (Montreal Neurological Institute-Hospital) of 㽶Ƶ created 100 a cappella recordings, each of a soprano singing a sentence. They then distorted the recordings along two fundamental auditory dimensions: spectral and temporal dynamics, and had 49 participants distinguish the words or the melodies of each song. The experiment was conducted in two groups of English and French speakers to enhance reproducibility and generalizability. The experiment is demonstrated here:

They found that for both languages, when the temporal information was distorted, participants had trouble distinguishing the speech content, but not the melody. Conversely, when spectral information was distorted, they had trouble distinguishing the melody, but not the speech. This shows that speech and melody depend on different acoustical features.

To test how the brain responds to these different sound features, the participants were then scanned with functional magnetic resonance imaging (fMRI) while they distinguished the sounds. The researchers found that speech processing occurred in the left auditory cortex, while melodic processing occurred in the right auditory cortex.

Music and speech exploit different ends of the spectro-temporal continuum

Next, they set out to test how degradation in each acoustic dimension would affect brain activity. They found that degradation of the spectral dimension only affected activity in the right auditory cortex, and only during melody perception, while degradation of the temporal dimension affected only the left auditory cortex, and only during speech perception. This shows that the differential response in each hemisphere depends on the type of acoustical information in the stimulus.

Previous studies in animals have found that neurons in the auditory cortex respond to particular combinations of spectral and temporal energy, and are highly tuned to sounds that are relevant to the animal in its natural environment, such as communication sounds. For humans, both speech and music are important means of communication. This study shows that music and speech exploit different ends of the spectro-temporal continuum, and that hemispheric specialization may be the nervous system’s way of optimizing the processing of these two communication methods.

Solving the mystery of hemispheric specialization

“It has been known for decades that the two hemispheres respond to speech and music differently, but the physiological basis for this difference remained a mystery,” says Philippe Albouy, the study’s first author. “Here we show that this hemispheric specialization is linked to basic acoustical features that are relevant for speech and music, thus tying the finding to basic knowledge of neural organization.”

were published in the journal Science on Feb. 28, 2020. It was funded by a Banting fellowship to Albouy and by grants to senior author Robert Zatorre from the Canadian Institutes for Health Research and from the Canadian Institute for Advanced Research. A cappella recordings were made with the help of 㽶Ƶ’s Schulich School of Music.

The Neuro

(The Montreal Neurological Institute-Hospital) is a world-leading destination for brain research and advanced patient care. Since its founding in 1934 by renowned neurosurgeon Dr. Wilder Penfield, The Neuro has grown to be the largest specialized neuroscience research and clinical center in Canada, and one of the largest in the world. The seamless integration of research, patient care, and training of the world’s top minds make The Neuro uniquely positioned to have a significant impact on the understanding and treatment of nervous system disorders. In 2016, The Neuro became the first institute in the world to fully embrace the Open Science philosophy, creating the Tanenbaum Open Science Institute. The Montreal Neurological Institute is affiliated with 㽶Ƶ and is a Killam Institution. The Montreal Neurological Hospital is part of the Neuroscience Mission of the 㽶Ƶ Health Centre. In 2020, The Neuro launched its largest fundraising campaign in history, Brains Need Open Minds.

The Neuro logoMcGill logo

The Neuro (Montreal Neurological Institute-Hospital)is a bilingual academic healthcare institution. We are aMcGill research and teaching institute; delivering high-quality patient care, as part of the Neuroscience Mission of the 㽶Ƶ Health Centre.We areproud to be a Killam Institution, supported by the Killam Trusts.

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