Oscillatory Dynamics in the Frontoparietal Attention Network during Sustained Attention in the Ferret

Sellers, Kristin K.; Yu, Chunxiu; Zhou, Zhe; Stitt, Iain; Li, Yuhui; Radtke‐Schuller, Susanne; Alagapan, Sankaraleengam; Fröhlich, Flavio

doi:10.1016/j.celrep.2016.08.055

Cited by 42 publications

(34 citation statements)

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“…For instance, Spyropoulos et al (Spyropoulos et al, 2018) recently reported that theta oscillations in the visual cortex elicited by visual stimuli decreased in amplitude when visual attention was directed. In addition, another recent study found arousal-reduced theta power in the high-order visual area (i.e., posterior parietal cortex) of the ferret brain (Stitt et al, 2018) despite its enhanced long-range theta synchrony with the prefrontal cortex during sustained attention reported by an earlier study (Sellers et al, 2016). In fact, a pioneering neuro-feedback study in the 1970s reported similar results of an association between occipital theta suppression and improved performance in a visual detection task (Beatty et al, 1974).…”

Section: Introductionmentioning

confidence: 78%

“…It should be noted that the substantial work conducted in the frontal cortex has found gamma oscillations to play an important role in pro-cognitive functions (Cho et al, 2015; Kim et al, 2016). On the neuronal spike levels, the spiking activities of the frontal cortex in the high gamma band were locked to theta oscillations in the frontal and posterior parietal cortices during sustained attention (Sellers et al, 2016). In our study, we found effective modulation of low gamma, but not high gamma, by frontal theta using cross-frequency coupling analysis.…”

Section: Discussionmentioning

confidence: 99%

“…In particular, in No-Go trials, we expected the recruitment of both frontal and visual theta oscillations, depending on the attentive state of the animal. This is because elaborate sustained attention (i.e., remaining alert while inhibiting a Go response) has been known to elicit control-related theta in the frontal cortex (Clayton et al, 2015; Sellers et al, 2016), while visual perception without attention has been reported to elicit theta oscillations in the visual area (Spyropoulos et al, 2018). By tracking short-term behavioral performance within a single experimental session, we investigated state-dependent changes of frontal and visual theta oscillations and their coupling with higher frequency oscillations (e.g., gamma oscillations) to confirm their functional dissociation.…”

Section: Introductionmentioning

confidence: 99%

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Functional dissociation of theta oscillations in the frontal and visual cortices and their long-range network during sustained attention

Han

Lee

Choi

2019

Preprint

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1Theta-band (4-12 Hz) activities in the frontal cortex have been thought to be a key mechanism of 2 sustained attention and goal-related behaviors, forming a phase-coherent network with task-related 3 sensory cortices for integrated neuronal ensembles. However, recent visual task studies found that 4 selective attention attenuates stimulus-related theta power in the visual cortex, suggesting a 5 functional dissociation of cortical theta oscillations. To investigate this contradictory behavior of 6 cortical theta, a visual Go/No-Go task was performed with electroencephalogram recording in mice. 7 During the No-Go period, transient theta oscillations were observed in both the frontal and visual 8 cortices, but theta oscillations of the two areas were prominent in different trial epochs. By 9 separating trial epochs based on subjects' short-term performance, we found that frontal theta was 10 prominent in good-performance epochs, while visual theta was prominent in bad-performance 11 epochs, exhibiting a functional dissociation of cortical theta rhythms. Furthermore, the two theta 12 rhythms also showed a heterogeneous pattern of phase-amplitude coupling with fast oscillations, 13 reflecting their distinct architecture in underlying neuronal circuitry. Interestingly, in good-14 performance epochs, where visual theta was relatively weak, stronger fronto-visual long-range 15 synchrony and shorter posterior-to-anterior temporal delay were found. These findings highlight a 16 previously overlooked aspect of long-range synchrony between distinct oscillatory entities in the 17 cerebral cortex and provide empirical evidence of a functional dissociation of cortical theta rhythms. 18 19 KEYWORDS 20 Theta rhythms, frontal theta, visual theta, electroencephalogram (EEG), Go/No-Go task 21 22 42 bottom right indicate 500 ms and 300 µV. (D) Summary of behavioral results. From all subjects (five 43 mice), and all sessions (10 days), data of 8,390 trials were collected. In this study, only the trials from CR 44 (n = 2,411) were analyzed. (E and F) (E) Time-frequency representation of grand-averaged event-related 45 spectral perturbation (ERSP) of each cortical area. In both the frontal and visual cortices, prominent theta 46 (4-12 Hz) oscillations were observed during 4 s of stimulus presentation (No-Go period). (F) Temporal 47 average (0.5 to 4 s) of theta oscillations in each cortical area. Numbers denote peak frequency of each 48 channel. FA: false alarm, Fr: frontal cortex, Vis: visual cortex, Amptd: amplitude, Freq: frequency. 49 4 / 35 50 Figure 2. Task performance and theta amplitude 51 (A) Distribution of pc (proportion correct) in all CR trials (n = 2,411). pc was calculated across 10 previous 52 trials. With a threshold of chance level (pc = 0.5), each trial was classified as either attentive (pc > 0.5) or 53 inattentive (pc ≤ 0.5) state. (B) Change of mean RT as function of pc. The RT of Hit trials decreased as pc 54 increased (Pearson's r = -.051, p < .05), suggesting the change of attentional level within the ...

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Section: Introductionmentioning

confidence: 78%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Functional dissociation of theta oscillations in the frontal and visual cortices and their long-range network during sustained attention

Han

Lee

Choi

2019

Preprint

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“…Recently, we reported that the 5-CSRTT engaged synchrony of oscillatory activity in the frontoparietal network of the ferret [16,17]. Phase synchronization both at the microscale of neuronal action potentials and the mesoscale of the population synaptic activity reflected in the local field potential was elevated in the theta-frequency range.…”

Section: Introductionmentioning

confidence: 92%

“…After successful training, the ferrets were surgically implanted with a chronic multichannel electrode array (2x8 tungsten electrode array, 250µm spacing, low-impedance reference electrode with the same length on the same array, MicroProbes Inc, Gaithersburg, MD) in LP/Pulvinar. Surgical procedure was similar to those previously described [16,22]. Briefly, ferrets were first injected with ketamine/xylazine (30 mg/kg of ketamine, 1-2 mg/kg of xylazine, IM) for anesthesia induction, and then were intubated and anesthetized with inhaled isoflurane (1.5-2%) in 100% medical oxygen (mechanically ventilated, 10-11 cc volume, 50 bpm).…”

Section: Surgerymentioning

confidence: 99%

Theta Oscillations Organize Spiking Activity in Higher-Order Visual Thalamus during Sustained Attention

Stitt

et al. 2017

Preprint

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Higher-order visual thalamus plays a fundamental but poorly understood role in attentiondemanding tasks. To investigate how neuronal dynamics in higher-order visual thalamus are modulated by sustained attention, we performed multichannel electrophysiological recordings in the lateral posterior-pulvinar complex (LP/pulvinar) in the ferret (Mustela putorius furo). We recorded single unit activity and local field potential during the performance of the 5-choice serial reaction time task (5-CSRTT) that is used in both humans and animals as an assay of sustained attention. We found that half of the units exhibited an increasing firing rate during the delay period before stimulus onset (attention-modulated units). In contrast, the non-attention-modulated units responded to the stimulus, but not during the delay period. Spike-field coherence of only the attention-modulated neurons significantly increased from the start of the delay period until screen touch, predominantly in the theta frequency band. In addition, theta power and theta-gamma phaseamplitude coupling were elevated throughout the delay period. Our findings suggest that the theta oscillation plays a central role in orchestrating thalamic signaling during sustained attention. SignificanceImpaired sustained attention can be deadly, as illustrated by the number of motor vehicle accidents that are caused by drivers not reacting quickly enough to unexpected events on the road.Understanding how electrical signaling in higher-order visual nuclei, such as the LP/pulvinar, is modulated during tasks that require sustained attention is an important step in achieving a mechanistic understanding of sustained attention, which will eventually lead to new strategies to prevent and treat impairment in sustained attention.peer-reviewed)

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Analysis of Visual Sensory Processing in the Brain and Brain-Computer Interfaces for Human Attention Control

Hramov

Короновский

Makarov

et al. 2021

Wavelets in Neuroscience

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Oscillatory Dynamics in the Frontoparietal Attention Network during Sustained Attention in the Ferret

Cited by 42 publications

References 50 publications

Functional dissociation of theta oscillations in the frontal and visual cortices and their long-range network during sustained attention

Functional dissociation of theta oscillations in the frontal and visual cortices and their long-range network during sustained attention

Theta Oscillations Organize Spiking Activity in Higher-Order Visual Thalamus during Sustained Attention

Analysis of Visual Sensory Processing in the Brain and Brain-Computer Interfaces for Human Attention Control

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