The Strength of Alpha–Beta Oscillatory Coupling Predicts Motor Timing Precision

Grabot, Laetitia; Kononowicz, Tadeusz W.; Tour, Tom Dupré la; Gramfort, Alexandre; Doyère, Valérie; Wassenhove, Virginie van

doi:10.1523/jneurosci.2473-18.2018

Cited by 25 publications

(26 citation statements)

References 94 publications

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“…This perceptual resolution account is also suggested by Samaha and Postle (2015) showing that occipital alpha frequency reflects the "refresh rate" of visual perception and occipital alpha represents the perceptual unit of temporal processing (Cecere et al, 2015). Consistent with this view, we predict that occipital alpha frequency should affect not only the encoding but also the retrieval and reproduction of temporal intervals, given that tACS-induced shifts in resting alpha frequency lead to shifts in subjective time experiences (Mioni et al, 2020), alpha-beta phase amplitude coupling correlates with time reproduction precision (Grabot et al, 2019), and that alpha frequency is central to the strengths of alpha-beta coupling. Future studies could investigate how interval reproduction performance is associated with alpha frequency modulation in healthy humans, as well as in the pre-clinical Alzheimer populations which show irregularities in parietal alpha oscillations (Montez et al, 2009).…”

Section: Discussionsupporting

confidence: 77%

“…Second, we found that oscillatory codes for temporal judgments were influenced by past trials while such codes for spatial judgments were not. Consistent with the idea of separable representations for space and time, spatial and temporal discounting are behaviorally distinctive from each other (Robinson, Michaelis, Thompson, & Wiener, 2019), estimating spatial distance can be subject to large errors (Zhao, 2018) while estimating suprasecond intervals can be performed with relatively high accuracy (Grabot et al, 2019), and spatial and temporal estimation errors distort in opposing manners (Brunec, Javadi, Zisch, & Spiers, 2017). The dissociation between space and time are also supported at the level of oscillatory signatures.…”

Section: Discussionmentioning

confidence: 71%

“…Some studies have looked at patterns of cortical low-frequency power when participants remember supra-second intervals. For example, the alpha-beta coupling strengths predict the precision of time reproduction (Grabot et al, 2019), and theta power in striatum and sensorimotor cortex discriminate rats' responses to THETA, ALPHA AND SPACE-TIME CODING 4 temporal interval comparisons (Gu, Kukreja, & Meck, 2018). Abundant evidence from single-unit recordings also suggests medial temporal lobe (MTL) structures form internally-generated assembly whose firing activities track time passage on scale of seconds (Itskov, Curto, Pastalkova, & Buzsáki, 2011;MacDonald, Lepage, Eden, & Eichenbaum, 2011;Pastalkova, Itskov, Amarasingham, & Buzsáki, 2008;Wang, Romani, Lustig, Leonardo, & Pastalkova, 2015).…”

Section: Introductionmentioning

confidence: 99%

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Common and distinct roles of frontal midline theta and occipital alpha oscillations in coding temporal intervals and spatial distances

Liang

Zheng

Isham

et al. 2020

Preprint

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Judging how far something is and how long it takes to get there are critical to memory and navigation. Yet, the neural codes for spatial and temporal information remain unclear, particularly how and whether neural oscillations might be important for such codes. To address these issues, participants traveled through teleporters in a virtual town while we simultaneously recorded scalp EEG. Participants judged the distance and time spent inside the teleporter. Our findings suggest that alpha power relates to distance judgments while frontal theta power relates to temporal judgments. In contrast, changes in alpha frequency and beta power indexed both spatial and temporal judgments. We also found evidence for fine-grained temporal coding and an effect of past trials on temporal but not spatial judgments. Together, these findings support partially independent coding schemes for spatial and temporal information, and suggest that low-frequency oscillations play important roles in coding both space and time.

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Section: Discussionsupporting

confidence: 77%

Section: Discussionmentioning

confidence: 71%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Common and distinct roles of frontal midline theta and occipital alpha oscillations in coding temporal intervals and spatial distances

Liang

Zheng

Isham

et al. 2020

Preprint

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“…Likewise, auditory frequency discrimination performance is impaired when subjects receive stimulation to the somatosensory cortex, but only when they are required to simultaneously attend to touch (Convento et al, 2018). Similarly, recent research has begun to demonstrate that time perception is highly linked to the amplitude and phase of beta (13–30 Hz) oscillations (Arnal et al, 2015; Kulashekhar et al, 2016; Wiener and Kanai, 2016; Morillon and Baillet, 2017; Grabot et al, 2019). That beta oscillations are also highly implicated in movement is likely no coincidence; movement and timing may be intrinsically linked.…”

Section: Discussionmentioning

confidence: 99%

Movement Improves the Quality of Temporal Perception and Decision-Making

Wiener

Zhou

Bader

et al. 2019

eNeuro

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A critical aspect of behavior is that mobile organisms must be able to precisely determine where and when to move. A better understanding of the mechanisms underlying precise movement timing and action planning is therefore crucial to understanding how we interact with the world around us. Recent evidence suggests that our experience of time is directly and intrinsically computed within the motor system, consistent with the theory of embodied cognition. To investigate the role of the motor system, we tested human subjects ( n = 40) on a novel task combining reaching and time estimation. In this task, subjects were required to move a robotic manipulandum to one of two physical locations to categorize a concurrently timed suprasecond. Critically, subjects were divided into two groups: one in which movement during the interval was unrestricted and one in which they were restricted from moving until the stimulus interval had elapsed. Our results revealed a higher degree of precision for subjects in the free-moving group. A further experiment ( n = 14) verified that these findings were not due to proximity to the target, counting strategies, bias, or movement length. A final experiment ( n = 10) replicated these findings using a within-subjects design, performing a time reproduction task, in which movement during encoding of the interval led to more precise performance. Our findings suggest that time estimation may be instantiated within the motor system as an ongoing readout of timing judgment and confidence.

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“…Oscillations of different frequencies are commonly coupled to each other, both within and between brain regions (Lakatos et al, 2005 ; Canolty et al, 2007 ). For example, delta phase is correlated with beta oscillation amplitude (Saleh et al, 2010 ; López-Azcárate et al, 2013 ; Arnal et al, 2015 ; Hamel-Thibault et al, 2018 ; Grabot et al, 2019 ), and beta phase is correlated with the amplitude of higher frequency oscillations (de Hemptinne et al, 2013 ; Meidahl et al, 2019 ). These complex correlations provide rich information regarding neural dynamics but make it difficult to distinguish cause from effect.…”

Section: Introductionmentioning

confidence: 99%

Interactions Between Motor Thalamic Field Potentials and Single-Unit Spiking Are Correlated With Behavior in Rats

Gaidica

Hurst

Cyr

et al. 2020

Front. Neural Circuits

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Field potential (FP) oscillations are believed to coordinate brain activity over large spatiotemporal scales, with specific features (e.g., phase and power) in discrete frequency bands correlated with motor output. Furthermore, complex correlations between oscillations in distinct frequency bands (phase-amplitude, amplitude-amplitude, and phase-phase coupling) are commonly observed. However, the mechanisms underlying FP-behavior correlations and cross-frequency coupling remain unknown. The thalamus plays a central role in generating many circuit-level neural oscillations, and single-unit activity in motor thalamus (Mthal) is correlated with behavioral output. We, therefore, hypothesized that motor thalamic spiking coordinates motor system FPs and underlies FP-behavior correlations. To investigate this possibility, we recorded wideband motor thalamic (Mthal) electrophysiology as healthy rats performed a two-alternative forced-choice task. Delta (1-4 Hz), beta (13-30 Hz), low gamma (30-70 Hz), and high gamma (70-200 Hz) power were strongly modulated by task performance. As in the cortex, the delta phase was correlated with beta/low gamma power and reaction time. Most interestingly, subpopulations of Mthal neurons defined by their relationship to the behavior exhibited distinct relationships with FP features. Specifically, neurons whose activity was correlated with action selection and movement speed were entrained to delta oscillations. Furthermore, changes in their activity anticipated power fluctuations in beta/low gamma bands. These complex relationships suggest mechanisms for commonly observed FP-FP and spike-FP correlations, as well as subcortical influences on motor output.

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The Strength of Alpha–Beta Oscillatory Coupling Predicts Motor Timing Precision

Cited by 25 publications

References 94 publications

Common and distinct roles of frontal midline theta and occipital alpha oscillations in coding temporal intervals and spatial distances

Common and distinct roles of frontal midline theta and occipital alpha oscillations in coding temporal intervals and spatial distances

Movement Improves the Quality of Temporal Perception and Decision-Making

Interactions Between Motor Thalamic Field Potentials and Single-Unit Spiking Are Correlated With Behavior in Rats

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