Human intracranial recordings link suppressed transients rather than 'filling-in' to perceptual continuity across blinks

Golan, Tal; Davidesco, Ido; Meshulam, Meir; Groppe, David M.; Mégevand, Pierre; Yeagle, Erin; Goldfinger, Matthew S; Harel, Michal; Melloni, Lucía; Schroeder, Charles E.; Deouell, Leon Y.; Mehta, Ashesh D.; Malach, Rafael

doi:10.7554/elife.17243

Cited by 50 publications

(85 citation statements)

References 49 publications

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“…Suppression of blink-related visual responses is commonly viewed as a product of a specialized 'hardwired' efferent copy pathway, linking oculomotor activity with suppression of visual responses (e.g., in the seminal work by Volkmann et al 1980;Volkmann et al 1982). This view is also supported by psychophysical (Bidder and Tomlinson 1997) and electrophysiological (Golan et al 2017) evidence linking blink suppression with saccadic suppression.…”

Section: Non-specific Prediction Mechanisms and Eye Blinksmentioning

confidence: 72%

“…To further control for potential duration differences between spontaneous and voluntary blinks, we matched the durations of the two blink types selecting a subset of spontaneous blink events and a subset of voluntary blink events so the two subsets will have a highly compatible duration distribution. This was done using an iterative procedure (Golan et al 2016): in each iteration, a pair of a spontaneous blink and a voluntary blink was added to the selected subsets. The criteria for selection were a duration difference of no more than 5 ms between the spontaneous and voluntary blink, and the minimization of the mean duration of the two subsets.…”

Section: Blink Duration Matching Controlmentioning

confidence: 99%

“…If we had the fMRI results alone, the most straightforward interpretation of the mid-and high-level visual cortex effects would have been that unpredictable external darkenings excite the high-level visual cortex whereas spontaneous and voluntary blinks, as well as self-initiated external darkenings, reduce its activity. However, timeresolved iEEG recordings acquired across the visual cortex during a similar task (Golan et al 2016) mandate a more nuanced interpretation: these recordings showed that the unpredictable darkenings caused a small, transient activity drop (see Golan et al, 2016…”

Section: Interpreting the Bold Responses In Light Of Previous Electromentioning

confidence: 99%

“…Spontaneous blinks during movie watching were found to be correlated with default mode activation (Nakano et al 2013). Finally, our recent intracranial EEG (iEEG) study of spontaneous blinks (Golan et al 2016) revealed that positive stimulus-driven activation transients in high order visual areas were suppressed during spontaneous blinks, potentially accounting for the lack of visual awareness of these interruptions.…”

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confidence: 99%

“…In particular, when eye blinks and external darkenings are contrasted, at least one major general cognitive factor confounds this contrast -predictability. Whereas eye blinks (either spontaneous or voluntary) are self-initiated and thus predictable, external darkenings, as applied in all of the studies that used this control (including Martin 2000, 2002;Nakano et al 2013;Golan et al 2016), were controlled by the experimenter and presented in an unpredictable manner.…”

mentioning

confidence: 99%

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Widespread Suppression of High-Order Visual Cortex During Blinks and External Predictable Visual Interruptions

Golan

Grossman

Deouell

et al. 2018

Preprint

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Spontaneous eye blinks generate frequent potent interruptions to the retinal input and yet go unnoticed. As such, they provide an attractive approach to the study of the neural correlates of visual awareness. Here, we tested the potential role of predictability in generating blink-related effects using fMRI. While participants attentively watched still images of faces and houses, we monitored naturally occurring spontaneous blinks and introduced three kinds of matched visual interruptions: cued voluntary blinks, self-initiated (and hence, predictable) external darkenings, and physically similar but unpredictable external darkenings. These events' impact was inspected using fMRI across the visual hierarchy. In early visual cortex, both spontaneous and voluntary blinks, as well as predictable and unpredictable external darkenings, led to largely similar positive responses in peripheral representations. In mid-and high-level visual cortex, all predictable conditions (spontaneous blinks, voluntary blinks, and self-initiated external darkenings) were associated with signal decreases. In contrast, unpredictable darkenings were associated with signal increases. These findings suggest that general-purpose prediction-related mechanisms are involved in producing a small but widespread suppression of mid-and high-order visual regions during blinks. Such suppression may down-regulate responses to predictable transients in the human visual hierarchy.

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Section: Non-specific Prediction Mechanisms and Eye Blinksmentioning

confidence: 72%

Section: Blink Duration Matching Controlmentioning

confidence: 99%

Section: Interpreting the Bold Responses In Light Of Previous Electromentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Widespread Suppression of High-Order Visual Cortex During Blinks and External Predictable Visual Interruptions

Golan

Grossman

Deouell

et al. 2018

Preprint

Self Cite

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Local field potentials, spiking activity, and receptive fields in human visual cortex

Luo,

Wang,

et al. 2023

Sci. China Life Sci.

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The concept of receptive field (RF) is central to sensory neuroscience. Neuronal RF properties have been substantially studied in animals, while those in humans remain nearly unexplored. Here, we measured neuronal RFs with intracranial local field potentials (LFPs) and spiking activity in human visual cortex (V1/V2/V3). We recorded LFPs via macro-contacts and discovered that RF sizes estimated from low-frequency activity (LFA, 0.5 -30 Hz) were larger than those estimated from low-gamma activity (LGA, 30 -60 Hz) and high-gamma activity (HGA, 60 -150 Hz). We then took a rare opportunity to record LFPs and spiking activity via microwires in V1 simultaneously.We found that RF sizes and temporal profiles measured from LGA and HGA closely matched those from spiking activity. In sum, this study reveals that spiking activity of neurons in human visual cortex could be well approximated by LGA and HGA in RF estimation and temporal profile measurement, implying the pivotal functions of LGA and HGA in early visual information processing.

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The Noisy Brain: Power of Resting-State Fluctuations Predicts Individual Recognition Performance

et al. 2019

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Graphical AbstractHighlights d Intracranial recordings in 26 patients during rest sessions and visual 1-back tasks d Amplitude of slow fluctuations at rest was negatively correlated with performance d The effect was specific to fluctuations in task-related cortical sites SUMMARYThe unique profile of strong and weak cognitive traits characterizing each individual is of a fundamental significance, yet their neurophysiological underpinnings remain elusive. Here, we present intracranial electroencephalogram (iEEG) measurements in humans pointing to resting-state cortical ''noise'' as a possible neurophysiological trait that limits visual recognition capacity. We show that amplitudes of slow (<1 Hz) spontaneous fluctuations in high-frequency power measured during rest were predictive of the patients' performance in a visual recognition 1-back task (26 patients, total of 1,389 bipolar contacts pairs). Importantly, the effect was selective only to task-related cortical sites. The prediction was significant even across long (mean distance 4.6 ± 2.8 days) lags. These findings highlight the level of the individuals' internal ''noise'' as a trait that limits performance in externally oriented demanding tasks.

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Human intracranial recordings link suppressed transients rather than 'filling-in' to perceptual continuity across blinks

Cited by 50 publications

References 49 publications

Widespread Suppression of High-Order Visual Cortex During Blinks and External Predictable Visual Interruptions

Widespread Suppression of High-Order Visual Cortex During Blinks and External Predictable Visual Interruptions

Local field potentials, spiking activity, and receptive fields in human visual cortex

The Noisy Brain: Power of Resting-State Fluctuations Predicts Individual Recognition Performance

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