Non‐stimulated regions in early visual cortex encode the contents of conscious visual perception

Kemenade, Bianca M. van; Wilbertz, Gregor; Müller, Annalena; Sterzer, Philipp

doi:10.1002/hbm.25731

Cited by 6 publications

(3 citation statements)

References 31 publications

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“…It should be noted that these results significantly extend the univariate results during the occlusion phase by showing that the pattern of activity in low‐level visual areas shows some commonalities during visible motion changes and occlusion. These results are also in line with a recent study which suggests that even with no stimulation in these regions, it is possible to decode information based on continuous perception (van Kemenade et al, 2022 ). Additionally, the successful prediction does not depend on the difference in activation height for upward versus downward tasks, as the lower visual regions did not show enhanced fMRI‐signals for occluded upward vs. downward motion in the univariate analysis.…”

Section: Discussionsupporting

confidence: 92%

Seeing and extrapolating motion trajectories share common informative activation patterns in primary visual cortex

Agostino

Merkel

Ball

et al. 2022

Human Brain Mapping

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The natural environment is dynamic and moving objects become constantly occluded, engaging the brain in a challenging completion process to estimate where and when the object might reappear. Although motion extrapolation is critical in daily life—imagine crossing the street while an approaching car is occluded by a larger standing vehicle—its neural underpinnings are still not well understood. While the engagement of low‐level visual cortex during dynamic occlusion has been postulated, most of the previous group‐level fMRI‐studies failed to find evidence for an involvement of low‐level visual areas during occlusion. In this fMRI‐study, we therefore used individually defined retinotopic maps and multivariate pattern analysis to characterize the neural basis of visible and occluded changes in motion direction in humans. To this end, participants learned velocity‐direction change pairings (slow motion‐upwards; fast motion‐downwards or vice versa) during a training phase without occlusion and judged the change in stimulus direction, based on its velocity, during a following test phase with occlusion. We find that occluded motion direction can be predicted from the activity patterns during visible motion within low‐level visual areas, supporting the notion of a mental representation of motion trajectory in these regions during occlusion.

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Section: Discussionsupporting

confidence: 92%

Seeing and extrapolating motion trajectories share common informative activation patterns in primary visual cortex

Agostino

Merkel

Ball

et al. 2022

Human Brain Mapping

View full text Add to dashboard Cite

show abstract

“…It should be noted that these results significantly extend the univariate results during the occlusion phase by showing that the pattern of activity in low-level visual areas shows some commonalities during visible motion and occlusion. These results are in line with a recent study which suggests that even with no stimulation in these regions, it is possible to decode information based on continuous perception (van Kemenade et al, 2022). Additionally, the successful prediction does not depend on the difference in activation height for upward vs downward tasks, as the lower visual regions did not show enhanced fMRI-signals for occluded upward vs. downward motion in the univariate analysis.…”

Section: Discussionsupporting

confidence: 93%

Seeing and Extrapolating motion trajectories share common informative activation patterns in primary visual cortex

Agostino

Merkel

Ball

et al. 2022

Preprint

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The natural environment is dynamic and moving objects become constantly occluded, engaging the brain in a challenging completion process to estimate where and when the object might reappear. Although motion extrapolation is critical in daily life – imagine crossing the street while an approaching car is occluded by a larger standing vehicle – its neural underpinnings are still not well understood. While the engagement of low-level visual cortex during dynamic occlusion has been postulated, most of the previous group-level fMRI-studies failed to find evidence for an involvement of low-level visual areas during occlusion. In this fMRI-study, we therefore used individually-defined retinotopic maps and multivariate pattern analysis to characterize the neural basis of visible and occluded motion in humans. To this end, participants learned velocity-direction pairings (slow motion-upwards; fast motion-downwards or vice versa) during a training phase without occlusion and judged the stimulus direction, based on its velocity, during a following test phase with occlusion. We find that occluded motion direction can be predicted from the activity patterns during visible motion within low-level visual areas, supporting the notion of a mental representation of motion trajectory in these regions during occlusion.Highlights* Dynamically occluded information is processed in low-level visual cortex* Specific regions inside low-level visual areas encode visible and dynamically occluded information* Overlap of visible and occluded informative activity patterns in the visual field suggest shared computational circuits in primary visual cortex

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“…Previous studies have extensively discussed the significant role of predictions in shaping perception (De Lange et al, 2018). It has been suggested that conscious perception is linked to the selection of the most probable predictive model (Hohwy et al, 2008;van Kemenade et al, 2020). A simplified Bayesian representation offers an explanation for predictive coding, where the most probable model corresponds to our prior knowledge before listening to the sound, and top-down predictions act as a likelihood (Hohwy et al, 2008).…”

Section: Introductionmentioning

confidence: 99%

Time course of EEG complexity reflects attentional engagement during listening to speech in noise

Eqlimi,

Bockstael,

Schönwiesner

et al. 2023

Eur J of Neuroscience

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Auditory distractions are recognized to considerably challenge the quality of information encoding during speech comprehension. This study explores electroencephalography (EEG) microstate dynamics in ecologically valid, noisy settings, aiming to uncover how these auditory distractions influence the process of information encoding during speech comprehension. We examined three listening scenarios: (1) speech perception with background noise (LA), (2) focused attention on the background noise (BA), and (3) intentional disregard of the background noise (BUA). Our findings showed that microstate complexity and unpredictability increased when attention was directed towards speech compared with tasks without speech (LA > BA & BUA). Notably, the time elapsed between the recurrence of microstates increased significantly in LA compared with both BA and BUA. This suggests that coping with background noise during speech comprehension demands more sustained cognitive effort. Additionally, a two‐stage time course for both microstate complexity and alpha‐to‐theta power ratio was observed. Specifically, in the early epochs, a lower level was observed, which gradually increased and eventually reached a steady level in the later epochs. The findings suggest that the initial stage is primarily driven by sensory processes and information gathering, while the second stage involves higher level cognitive engagement, including mnemonic binding and memory encoding.

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Non‐stimulated regions in early visual cortex encode the contents of conscious visual perception

Cited by 6 publications

References 31 publications

Seeing and extrapolating motion trajectories share common informative activation patterns in primary visual cortex

Seeing and extrapolating motion trajectories share common informative activation patterns in primary visual cortex

Seeing and Extrapolating motion trajectories share common informative activation patterns in primary visual cortex

Time course of EEG complexity reflects attentional engagement during listening to speech in noise

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