“Neural Efficiency” of Athletes’ Brain during Visuo-Spatial Task: An fMRI Study on Table Tennis Players

Guo, Zhongwen; Li, An-Min; Yu, Lin

doi:10.3389/fnbeh.2017.00072

Cited by 88 publications

(84 citation statements)

References 41 publications

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“…Specifically, lower reduction in amplitude of EEG oscillations at dominant alpha rhythms were observed during different posture keeping experiments. This may support "neural efficiency" hypothesis in sense of a more selective involvement of related cortical areas [Del Percio, 2009;Guo, 2017].…”

Section: Methodssupporting

confidence: 77%

EEG activity during balance platform test in humans

Khorev

Badarin

Antipov

et al. 2019

CAP

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In order to analyze different human brain states related to perception and maintaining of body posture, we implemented an experiment with a balance platform. It is known the cerebral cortex regulates subcortical postural centers to maintain upright balance and posture and balance demands. However, the cortical mechanisms that support standing balance remain elusive. In this work, we present an EEG-based analysis during execution of balance responses with distinct postural demands. The results suggest the existence of common features in the EEG structure associated with distinct activity during balance maintaining. This may give new directions for future research in the field of brain activity, and for the development of brain-computer interfaces.

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Section: Methodssupporting

confidence: 77%

EEG activity during balance platform test in humans

Khorev

Badarin

Antipov

et al. 2019

CAP

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“…A recent functional MRI (fMRI) study by Naito and Hirose (2014) provided novel evidence that the brain of a top-class football player (Neymar) relies on less neuronal resources in motor-related areas as compared to other athletes. Similar findings have been found in other sports disciplines such as table tennis where athletes show less brain activation during the execution of sports-related and sports-unrelated visuospatial tasks as compared to non-athletes (Guo et al, 2017). Moreover, several studies provide compelling evidence that there is a causal relationship between brain activation and behavioral performance (Orban et al, 2010;Peterson and Fling, 2018) or motor skill learning capabilities (Sun et al, 2007;Wadden et al, 2013), respectively.…”

Section: Diagnostics Of Neuroplasticity Using Non-invasive Brain Imagsupporting

confidence: 81%

Neurodiagnostics in Sports: Investigating the Athlete’s Brain to Augment Performance and Sport-Specific Skills

Seidel-Marzi

Ragert

2020

Front. Hum. Neurosci.

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Enhancing performance levels of athletes during training and competition is a desired goal in sports. Quantifying training success is typically accompanied by performance diagnostics including the assessment of sports-relevant behavioral and physiological parameters. Even though optimal brain processing is a key factor for augmented motor performance and skill learning, neurodiagnostics is typically not implemented in performance diagnostics of athletes. We propose, that neurodiagnostics via non-invasive brain imaging techniques such as functional near-infrared spectroscopy (fNIRS) will offer novel perspectives to quantify training-induced neuroplasticity and its relation to motor behavior. A better understanding of such a brain-behavior relationship during the execution of sport-specific movements might help to guide training processes and to optimize training outcomes. Furthermore, targeted non-invasive brain stimulation such as transcranial direct current stimulation (tDCS) might help to further enhance training outcomes by modulating brain areas that show training-induced neuroplasticity. However, we strongly suggest that ethical aspects in the use of non-invasive brain stimulation during training and/or competition need to be addressed before neuromodulation can be considered as a performance enhancer in sports.

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“…Critically, this finding allows us to conclude that it is experienced with the task and not the sport‐specific nature of the ‘expert’ task that modulates brain activity driven via MI. The recruitment of additional regions across both hemispheres that we observed between tasks with a low vs. high degree of experience is in alignment with previous literature that suggests brain activation during novice performance reflects an inefficient and unorganized network (Haufler et al ., ; Milton et al ., ; Percio et al ., ; Del Percio et al ., ; Bar & DeSouza, ; Guo et al ., ), and that greater recruitment of bilateral regions involved in motor planning may be indicative of the additional ‘effort’ required (Milton et al ., ; Percio et al ., ; Del Percio et al ., ; Guo et al ., ).…”

Section: Discussionmentioning

confidence: 99%

Experience modulates motor imagery‐based brain activity

Kraeutner

McWhinney

Solomon

et al. 2018

Eur J of Neuroscience

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Whether or not brain activation during motor imagery (MI), the mental rehearsal of movement, is modulated by experience (i.e. skilled performance, achieved through long-term practice) remains unclear. Specifically, MI is generally associated with diffuse activation patterns that closely resemble novice physical performance, which may be attributable to a lack of experience with the task being imagined vs. being a distinguishing feature of MI. We sought to examine how experience modulates brain activity driven via MI, implementing a within- and between-group design to manipulate experience across tasks as well as expertise of the participants. Two groups of 'experts' (basketball/volleyball athletes) and 'novices' (recreational controls) underwent magnetoencephalography (MEG) while performing MI of four multi-articular tasks, selected to ensure that the degree of experience that participants had with each task varied. Source-level analysis was applied to MEG data and linear mixed effects modelling was conducted to examine task-related changes in activity. Within- and between-group comparisons were completed post hoc and difference maps were plotted. Brain activation patterns observed during MI of tasks for which participants had a low degree of experience were more widespread and bilateral (i.e. within-groups), with limited differences observed during MI of tasks for which participants had similar experience (i.e. between-groups). Thus, we show that brain activity during MI is modulated by experience; specifically, that novice performance is associated with the additional recruitment of regions across both hemispheres. Future investigations of the neural correlates of MI should consider prior experience when selecting the task to be performed.

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“Neural Efficiency” of Athletes’ Brain during Visuo-Spatial Task: An fMRI Study on Table Tennis Players

Cited by 88 publications

References 41 publications

EEG activity during balance platform test in humans

EEG activity during balance platform test in humans

Neurodiagnostics in Sports: Investigating the Athlete’s Brain to Augment Performance and Sport-Specific Skills

Experience modulates motor imagery‐based brain activity

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