Acute Exercise Modulates Feature-selective Responses in Human Cortex

Bullock, Tom; Elliott, J. C.; Serences, John T.; Giesbrecht, Barry

doi:10.1162/jocn_a_01082

Cited by 50 publications

(60 citation statements)

References 55 publications

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“…For the same reasons we don't believe that the modulations in the N1 and P2 we observed are due to increases in noise due to movement, respiration or perspiration, given the slow speed of biking and the very similar noise levels compared to studies of indoor biking. We believe that any effects of acute exercise on brain processing would require a much higher intensity of biking Outdoor Cycling and Auditory P300 29 (see Pontifex & Hillman, 2007;Yagi, Coburn, Estes, & Arruda, 1999;Grego et al, 2004;Bullock et al, 2017). In follow up research we plan to push individuals to faster biking paces and investigate changes in acute behavioural effects, ERP measurement ability, and measured noise in the data.…”

Section: Discussionmentioning

confidence: 99%

Taking off the training wheels: Measuring auditory P3 during outdoor cycling using an active wet EEG system

Scanlon

Townsend

Cormier

et al. 2017

Preprint

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Mobile EEG allows the investigation of brain activity in increasingly complex environments. In this study, EEG equipment was adapted for use and transportation in a backpack while cycling.Participants performed an auditory oddball task while cycling outside and sitting in an isolated chamber inside the lab. Cycling increased EEG noise and marginally diminished alpha amplitude. However, this increased noise did not influence the ability to measure reliable event related potentials (ERP). The P3 was similar in topography, and morphology when outside on the bike, with a lower amplitude in the outside cycling condition. There was only a minor decrease in the statistical power to measure reliable ERP effects. Unexpectedly, when biking outside significantly decreased P2 and increased N1 amplitude were observed when evoked by both standards and targets compared with sitting in the lab. This may be due to attentional processes filtering the overlapping sounds between the tones used and similar environmental frequencies.This study established methods for mobile recording of ERP signals. Future directions include investigating auditory P2 filtering inside the laboratory.

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Section: Discussionmentioning

confidence: 99%

Taking off the training wheels: Measuring auditory P3 during outdoor cycling using an active wet EEG system

Scanlon

Townsend

Cormier

et al. 2017

Preprint

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“…exercise by means of EEG event-related brain potentials (ERPs) as a way to pinpoint the brain correlates of (task relevant) stimulus processing under physical effort [13] [14][15] [16][17] [18]. Here, we take a step further by analysing power spectral changes time-locked to the (task) stimulus instead of ERPs.…”

Section: An Alternative Line Of Investigations Have Focused On Targetmentioning

confidence: 99%

“…[8][9][10][11][12][13][14] parametric paired t-test maps comparing the averaged spectral power across subjects over time (x-axes) and frequency (y-axes) during moderate-to-high intensity and light intensity exercise in standard trials. The enclosed areas denote significant clusters of channels and time with p < 0.025.…”

Section: Cc-by-nc-nd 40 International Licensementioning

confidence: 99%

Tonic and transient oscillatory brain activity during acute exercise

Ciria

Luque‐Casado

Sanabria

et al. 2017

Preprint

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The physiological changes that occur in the main body systems and organs during physical exercise are well described in the literature. Despite the key role of brain in processing afferent and efferent information from organ systems to coordinate and optimize their functioning, little is known about how the brain works during exercise. The present study investigated tonic and transient oscillatory brain activity during a single bout of aerobic exercise. Twenty young males (19-32 years old) were recruited for two experimental sessions on separate days. Electroencephalographic (EEG) activity was recorded during a session of cycling at 80% (moderate-to-high intensity) of VO 2max (maximum aerobic capacity) while performing an oddball task where participants had to detect infrequent targets presented among frequent non-targets. This was compared to a (baseline) light intensity session (30% VO 2max ). The light intensity session was included to control for any potential effect of dual-tasking (i.e., pedaling and performing the oddball task). A warm-up and cool down periods were completed before and after exercise, respectively. A cluster-based nonparametric permutations test showed an increase in power across the entire frequency spectrum during the moderate-to-high intensity exercise, with respect to light intensity. Further, we found that the more salient target lead to lower increase in (stimulus-evoked) theta power in the 80% VO 2max with respect to the light intensity condition. On the contrary, higher decrease alpha and lower beta power was found for standard trials in the moderate-to-high exercise condition than in the light exercise condition. The present study unveils, for the first time, a complex brain activity pattern during acute exercise (at 80% of maximum aerobic capacity). These findings might help to elucidate the nature of changes that occur in the brain during physical exertion.

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“…The parameters of these channel response estimates can then be used to quantify the spatially selective response. This method was initially applied to fMRI data (Brouwer & Heeger, 2009Ester, Sprague, & Serences, 2015;Naselaris, Kay, Nishimoto, & Gallant, 2011;Serences & Saproo, 2012) and has been recently applied to EEG recorded at the scalp (Bullock, Elliott, Serences, & Giesbrecht, 2017;Foster et al, 2016Foster et al, , 2017Garcia, Srinivasan, & Serences, 2013;Samaha et al, 2016).…”

Section: Inverted Encoding Modelmentioning

confidence: 99%

Dual process coding of recalled locations in human oscillatory brain activity

MacLean

Bullock

Giesbrecht

2018

Preprint

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A mental representation of the location of an object can be constructed using sensory information selected from the environment and information stored internally. Human electrophysiological evidence indicates that behaviorally relevant locations, regardless of the source of sensory information, are represented in alphaband oscillations suggesting a shared process. Here we present evidence from human subjects of either sex for two distinct alpha-band based processes that separately support the representation of location, exploiting sensory evidence sampled either externally or internally. Significance StatementOur sensory environment and our internal trains of thought are coded in patterns of brain activity and are used to guide coherent behavior. Oscillations in the alpha frequency band are a predominant feature of human brain activity. This oscillation plays a central role in both selective attention and working memory, suggesting that these important cognitive functions are mediated by a unitary mechanism. We show that the alpha oscillation reflects two distinct processes, one that is supported by continuous sampling of the external sensory environment, and one that is based on sampling from internal representations coded in visual shortterm memory. This represents a significant change in our understanding of the nature of alpha oscillations and their relationship to attention and memory.

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Acute Exercise Modulates Feature-selective Responses in Human Cortex

Cited by 50 publications

References 55 publications

Taking off the training wheels: Measuring auditory P3 during outdoor cycling using an active wet EEG system

Taking off the training wheels: Measuring auditory P3 during outdoor cycling using an active wet EEG system

Tonic and transient oscillatory brain activity during acute exercise

Dual process coding of recalled locations in human oscillatory brain activity

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