Summary
Entrainment to music is a culturally widespread activity with increasingly recognized pro-social and
therapeutic effects. Music powerfully compels us to move to the musical rhythm, showcasing the
remarkable ability of humans to perceive and produce rhythmic inputs. However, the underlying
functional mechanisms remain unknown. One view, which dates back to Darwin, is that the relevant
mechanisms are ancient and anchored in the evolutionary oldest subcortical parts of the brain.
However, recent research argues that rhythm perception is a complex cognitive function involving
temporally precise communication between cortical sensory and motor regions, even in the absence
of overt body movement or intention to move.
This project aims to uncover these mechanisms by combining concepts and methods of
experimental psychology and cognitive neuroscience. Specifically, the research will (i) unravel the
mechanisms at the interface of rhythmic inputs, motor skills and brain activity, (ii) establish the
active role of motor representations in rhythm perception, (iii) track the development of these
processes even prior to language in infants, and (iv) investigate the physiopathology and restoration
of these processes in brain-damaged patients.
To achieve these objectives, the project will use a comparable method across different experimental
settings, the frequency-tagging approach, whose reliability and advantages have been recently
established as an innovative method to capture neural entrainment to rhythm in humans. Results
will provide important knowledge into how psychological, environmental and neural mechanisms
affect such entrainment. Clarifying these mechanisms provides an optimal framework to unravel the
role of an intrinsic sensory-motor coupling underlying perception and how this coupling develops
over the lifespan. It is also critical for optimising clinical rehabilitation practices using music as a
powerful non-verbal cross-cultural means of communication.
therapeutic effects. Music powerfully compels us to move to the musical rhythm, showcasing the
remarkable ability of humans to perceive and produce rhythmic inputs. However, the underlying
functional mechanisms remain unknown. One view, which dates back to Darwin, is that the relevant
mechanisms are ancient and anchored in the evolutionary oldest subcortical parts of the brain.
However, recent research argues that rhythm perception is a complex cognitive function involving
temporally precise communication between cortical sensory and motor regions, even in the absence
of overt body movement or intention to move.
This project aims to uncover these mechanisms by combining concepts and methods of
experimental psychology and cognitive neuroscience. Specifically, the research will (i) unravel the
mechanisms at the interface of rhythmic inputs, motor skills and brain activity, (ii) establish the
active role of motor representations in rhythm perception, (iii) track the development of these
processes even prior to language in infants, and (iv) investigate the physiopathology and restoration
of these processes in brain-damaged patients.
To achieve these objectives, the project will use a comparable method across different experimental
settings, the frequency-tagging approach, whose reliability and advantages have been recently
established as an innovative method to capture neural entrainment to rhythm in humans. Results
will provide important knowledge into how psychological, environmental and neural mechanisms
affect such entrainment. Clarifying these mechanisms provides an optimal framework to unravel the
role of an intrinsic sensory-motor coupling underlying perception and how this coupling develops
over the lifespan. It is also critical for optimising clinical rehabilitation practices using music as a
powerful non-verbal cross-cultural means of communication.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/801872 |
| Start date: | 01-04-2019 |
| End date: | 31-03-2025 |
| Total budget - Public funding: | 1 494 900,00 Euro - 1 494 900,00 Euro |
Cordis data
Original description
Entrainment to music is a culturally widespread activity with increasingly recognized pro-social andtherapeutic effects. Music powerfully compels us to move to the musical rhythm, showcasing the
remarkable ability of humans to perceive and produce rhythmic inputs. However, the underlying
functional mechanisms remain unknown. One view, which dates back to Darwin, is that the relevant
mechanisms are ancient and anchored in the evolutionary oldest subcortical parts of the brain.
However, recent research argues that rhythm perception is a complex cognitive function involving
temporally precise communication between cortical sensory and motor regions, even in the absence
of overt body movement or intention to move.
This project aims to uncover these mechanisms by combining concepts and methods of
experimental psychology and cognitive neuroscience. Specifically, the research will (i) unravel the
mechanisms at the interface of rhythmic inputs, motor skills and brain activity, (ii) establish the
active role of motor representations in rhythm perception, (iii) track the development of these
processes even prior to language in infants, and (iv) investigate the physiopathology and restoration
of these processes in brain-damaged patients.
To achieve these objectives, the project will use a comparable method across different experimental
settings, the frequency-tagging approach, whose reliability and advantages have been recently
established as an innovative method to capture neural entrainment to rhythm in humans. Results
will provide important knowledge into how psychological, environmental and neural mechanisms
affect such entrainment. Clarifying these mechanisms provides an optimal framework to unravel the
role of an intrinsic sensory-motor coupling underlying perception and how this coupling develops
over the lifespan. It is also critical for optimising clinical rehabilitation practices using music as a
powerful non-verbal cross-cultural means of communication.
Status
SIGNEDCall topic
ERC-2018-STGUpdate Date
27-04-2024
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