Neural correlates of motor expertise: Extensive motor training and cortical changes

Calmels, Claire

doi:10.1016/j.brainres.2019.146323

Cited by 25 publications

(22 citation statements)

References 143 publications

(315 reference statements)

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“…After three weeks of fluency shaping training, connectivity was increased between the left anterior superior temporal gyrus and the left articulatory motor cortex, and hyperconnectivity was reduced between the left IFG pars opercularis and the sensory feedback processing left supramarginal gyrus (Kell et al, 2018). This observation suggests a treatment-induced boost of auditory-to-motor coupling and likely indicates neuroplasticity induced by sensorimotor learning (Calmels, 2020).…”

Section: Introductionmentioning

confidence: 82%

Fluency shaping increases integration of the command-to-execution and the auditory-to-motor pathways in persistent developmental stuttering

Korzeczek¹,

Primaßin

Gudenberg

et al. 2020

Preprint

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Developmental stuttering is a fluency disorder with anomalies in the neural speech motor system. Fluent speech requires multifunctional network formations. Currently, it is unclear which functional domain is targeted by speech fluency interventions. Here, we tested the impact of fluency-shaping on resting-state fMRI connectivity of the speech planning, articulatory convergence, sensorimotor integration, and inhibitory control network. Furthermore, we examined white matter metrics of major speech tracts. Improved fluency was accompanied by an increased synchronization within the sensorimotor integration network. Specifically, two connections were strengthened, left laryngeal motor cortex and right superior temporal gyrus showed increased connectivity with the left inferior frontal gyrus. The integration of the command-to-execution and auditory-motor pathway was strengthened. Since we investigated task-free brain activity, we assume that our findings are not biased to network activity involved in compensation. No alterations were found within white matter microstructure. But, brain-behavior relationships changed. We found a heightened negative correlation between stuttering severity and fractional anisotropy in the superior longitudinal fasciculus, and a heightened positive correlation between the psycho-social impact of stuttering and fractional anisotropy in the right frontal aslant tract. Taken together, structural and functional connectivity of the sensorimotor integration and inhibitory control network shape speech motor learning.

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Section: Introductionmentioning

confidence: 82%

Fluency shaping increases integration of the command-to-execution and the auditory-to-motor pathways in persistent developmental stuttering

Korzeczek¹,

Primaßin

Gudenberg

et al. 2020

Preprint

View full text Add to dashboard Cite

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“…Note that, in literate adults, HW is highly automatic; it consists of rapid sequences of short movements with fast changes in direction, resulting in high-quality, stable, and consistent reproduction of graphs. It is clearly an ecological example of motor expertise like playing a musical instrument ( Palmis et al, 2017 ; Calmels, 2020 ). Therefore, the convergence with research from perceptual and motor expertise could be fruitful for a deeper understanding of the cognitive mechanism underpinning the benefit from HW training in visual graph recognition (see, e.g., Folstein and Monfared, 2019 ).…”

Section: Discussionmentioning

confidence: 99%

From Hand to Eye With the Devil In-Between: Which Cognitive Mechanisms Underpin the Benefit From Handwriting Training When Learning Visual Graphs?

Fernandes

Araújo

2021

Front. Psychol.

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Cognitive science has recently shown a renewed interest on the benefit from training in handwriting (HW) when learning visual graphs, given that this learning experience improves more subsequent visual graph recognition than other forms of training. However, the underlying cognitive mechanism of this HW benefit has been elusive. Building on the 50 years of research on this topic, the present work outlines a theoretical approach to study this mechanism, specifying testable hypotheses that will allow distinguishing between confronting perspectives, i.e., symbolic accounts that hold that perceptual learning and visual analysis underpin the benefit from HW training vs. embodied sensorimotor accounts that argue for motoric representations as inner part of orthographic representations acquired via HW training. From the evidence critically revisited, we concluded that symbolic accounts are parsimonious and could better explain the benefit from HW training when learning visual graphs. The future challenge will be to put at test the detailed predictions presented here, so that the devil has no longer room in this equation.

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“…Further, while many studies that investigated skill- and experience-related changes in the human brain structure report increases in volume, area, or thickness, the large amounts of knowledge, experience, and skills obtained during a lifetime are ultimately not likely to be represented in the brain by cumulative, continual increases in structural measures (Wenger et al, 2017; Calmels et al, 2019). Indeed, selection, deletion and pruning are effective mechanisms that occur throughout the nature, including brain development.…”

Section: Discussionmentioning

confidence: 99%

Musicianship can be decoded from magnetic resonance images

Puoliväli

Sipola

Thiede

et al. 2020

Preprint

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Learning induces structural changes in the brain. Especially repeated, long-term behaviors, such as extensive training of playing a musical instrument, are likely to produce characteristic features to brain structure. However, it is not clear to what extent such structural features can be extracted from magnetic resonance images of the brain. Here we show that it is possible to predict whether a person is a musician or a non-musician based on the thickness of the cerebral cortex measured at 148 brain regions encompassing the whole cortex. Using a supervised machine learning technique called support vector machines, we achieved significant (k = 0.321, p < 0.001) agreement between the actual and predicted participant groups of 30 musicians and 85 non-musicians. The areas contributing to the prediction were mostly in the frontal, parietal, and occipital lobes of the left hemisphere. Our results suggest that decoding an acquired skill from magnetic resonance images of brain structure is feasible to some extent. Further, the distribution of the areas that were informative in the classification, which mostly, but not entirely overlapped with earlier findings, implies that decoding-based analyses of structural properties of the brain can reveal novel aspects of musical aptitude.

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Neural correlates of motor expertise: Extensive motor training and cortical changes

Cited by 25 publications

References 143 publications

Fluency shaping increases integration of the command-to-execution and the auditory-to-motor pathways in persistent developmental stuttering

Fluency shaping increases integration of the command-to-execution and the auditory-to-motor pathways in persistent developmental stuttering

From Hand to Eye With the Devil In-Between: Which Cognitive Mechanisms Underpin the Benefit From Handwriting Training When Learning Visual Graphs?

Musicianship can be decoded from magnetic resonance images

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