Neural repetition suppression modulates time perception: Evidence from electrophysiology and pupillometry

Kruijne, Wouter; Olivers, Christian N. L.; Rijn, Hedderik van

doi:10.1101/2020.07.31.230508

Cited by 5 publications

(16 citation statements)

References 137 publications

(215 reference statements)

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“…The results indicate that for the first three of those dimensions, changes between the start-and end-marker of an interval resulted in a dilation of perceived duration compared to trials where the start-and end-marker were the same. These findings show that the 'change bias' that we found in earlier work (Kruijne et al, 2020) is a general finding that is not limited to changes in location. At the same time, the results suggest that the change bias shows selectivity, as changes in Faces, Orientation and Luminance did not affect time perception in the same way.…”

Section: Discussionsupporting

confidence: 78%

“…In an earlier study we have demonstrated that the change bias manifests when stimuli marking the start and end of an interval either repeat or change in location (Kruijne et al, 2020). The results suggested that sensory responses to the offset marker were attenuated upon repetition compared to changes, which in turn affected the perceived duration.…”

Section: Experiments 1 : Location and Face Identitymentioning

confidence: 90%

“…Recently, we have presented an experimental paradigm that might overcome this convolution (Kruijne et al, 2020). In this study, participants timed intervals that were presented by means of briefly flashing on-and offset markers (cf.…”

Section: Feature Changes Affect Time Perceptionmentioning

confidence: 99%

“…This primary analysis was based on a hypothesis-driven model, which makes several assumptions derived from earlier observations (Kruijne et al, 2020). Most importantly, the model relies on the assumption that experimental conditions (trial type and block type) could affect the shift of the psychometric curves, but not their slope.…”

Section: Stimuli and Materials Stimuli Were Presented On An Lg-22mb3mentioning

confidence: 99%

“…All interval markers (including those in reference trials) were dark green open squares (as in Kruijne et al, 2020), which were somewhat less straining on the eyes than the white FEATURE CHANGES AFFECT TIME PERCEPTION 21 squares used in Experiment 1. In Size-blocks, this square had sides of either 3.85°or 11.41, which constitutes a change of ±50% with respect to its size in reference trials and Location-blocks (7.67°).…”

Section: Stimuli and Materials Stimuli And Displays Used In Differenmentioning

confidence: 99%

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Change biases identify the features that drive time perception

Kruijne¹,

Rijn²

2020

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[This paper has not been peer reviewed. Please do not copy or cite without author's permission.] Time perception is malleable, and the perceived duration of stimuli can be strongly affected by the sensory response they evoke. Such ‘temporal illusions’ provide a window on how different sensory systems contribute to our sense of time. Evidence suggests that the sensory response to different features affects time perception to different extents, mediated by the level of arousal or surprise that they evoke. This, however, makes it difficult to disentangle effects of the sensory response itself from the derived arousal or surprise effects. Here, we demonstrate that time perception is differentially affected by different stimulus features when arousal and surprise are kept constant. In four temporal discrimination experiments, participants judged the duration of an interval marked by two briefly presented visual markers. Markers either repeated or changed along one of six feature dimensions, in a manner fully predictable to participants. Repetitions and changes would modulate sensory response magnitudes due to neural repetition suppression. Results showed that intervals were perceived as longer when markers changed in location, size or numerosity. Conversely, changes in face identity, orientation or luminance did not affect time perception. These results point to neural and functional selectivity in the way different stimulus features affect time perception.

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Section: Discussionsupporting

confidence: 78%

Section: Experiments 1 : Location and Face Identitymentioning

confidence: 90%

Section: Feature Changes Affect Time Perceptionmentioning

confidence: 99%

Section: Stimuli and Materials Stimuli Were Presented On An Lg-22mb3mentioning

confidence: 99%

Section: Stimuli and Materials Stimuli And Displays Used In Differenmentioning

confidence: 99%

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Change biases identify the features that drive time perception

Kruijne¹,

Rijn²

2020

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Temporal context actively shapes EEG signatures of time perception

Damsma

Schlichting

Rijn

2020

Preprint

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Our subjective perception of time is optimized to temporal regularities in the environment. This is illustrated by the central tendency effect: when estimating a range of intervals, short intervals are overestimated whereas long intervals are underestimated to reduce the overall estimation error. Most models of interval timing ascribe this effect to the weighting of the current interval with previous memory traces after the interval has been perceived. Alternatively, the perception of the duration could already be flexibly tuned to its temporal context. We investigated this hypothesis using an interval reproduction task with a shorter and longer interval range. As expected, reproductions were biased towards the subjective mean of each presented range. EEG analysis showed that temporal context affected neural dynamics during the perception phase. Specifically, longer previous durations decreased CNV and P2 amplitude and increased beta power. In addition, multivariate pattern analysis showed that it is possible to decode context from the transient EEG signal quickly after the onset and offset of the perception phase. Together, these results suggest that temporal context creates dynamic expectations which actively affect the perception of duration.The subjective sense of duration does not arise in isolation, but is informed by previous experiences. This is demonstrated by abundant evidence showing that duration estimates are biased towards previously perceived time intervals. However, it is yet unknown whether this temporal context actively affects perception or asserts its influence in later, post-perceptual stages as proposed by most current formal models of this task. Using an interval reproduction task, we here show that EEG signatures flexibly adapt to the temporal context during perceptual encoding. Furthermore, interval history could be decoded from the transient EEG signal even when the current duration was identical.All in all, our results suggest that context actively influences perception.

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Memory for stimulus duration is not bound to spatial information

Kruijne

Olivers

Rijn

2020

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Different models have been proposed to explain how the human brain derives an accurate sense of time. One specific class of models, intrinsic models, state that temporal information of a stimulus is represented much like other features such as color and location, bound together to form a coherent percept. Here we explored to what extent this holds for temporal information after it has been perceived and is held in working memory for subsequent comparison. We recorded EEG of participants who were asked to time stimuli at lateral positions of the screen followed by comparison stimuli presented in the center. Using well-established markers of working memory maintenance, we investigated whether the usage of temporal information evoked neural signatures that were indicative of the location where the stimuli had been presented, both during maintenance and during comparison. Neural and behavioral measures, including the contralateral delay activity, lateralized alpha suppression and decoding analyses through time, all supported the same conclusion: while the representation of location was strongly involved during the perception of temporal information, once temporal information was committed to memory it no longer showed any relation to spatial information during maintenance or during comparisons. These results support a model where the initial perception of a stimulus involves intrinsic computations, but that this information is subsequently translated to a stimulus-independent format to be used to further guide behavior.

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Neural repetition suppression modulates time perception: Evidence from electrophysiology and pupillometry

Cited by 5 publications

References 137 publications

Change biases identify the features that drive time perception

Change biases identify the features that drive time perception

Temporal context actively shapes EEG signatures of time perception

Memory for stimulus duration is not bound to spatial information

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