Chronotopic maps in human supplementary motor area

Protopapa, Foteini; Hayashi, Masamichi J.; Kulashekhar, Shrikanth; Zwaag, Wietske van der; Battistella, Giovanni; Murray, Micah M.; Kanai, Ryota; Bueti, Domenica

doi:10.1371/journal.pbio.3000026

Cited by 101 publications

(93 citation statements)

References 52 publications

(74 reference statements)

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“…The hypothesis that perceived duration is achieved through leaky integration of stimulus-related and stimulus-unrelated sensory input is particularly relevant to the debate on models for the perception of time in the scale that ranges from tens of milliseconds up to a few seconds. Our results are in line with other work that assumes temporal integration processes behind the encoding of the passage of time (30,31) and are also in accordance with the idea that sensory-specific areas contribute to time perception (3,32). They are harder to reconcile with the amodal central clock theory (1).…”

Section: Integration Of Sensory Drive and Alternative Modelssupporting

confidence: 92%

A sensory integration account for time perception

Toso

Fassihi

Paz

et al. 2020

Preprint

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The connection between stimulus perception and time perception remains unknown. The present study combines human and rat psychophysics with sensory cortical neuronal firing to construct a computational model for the percept of elapsed time embedded within sense of touch. When subjects judged the duration of a vibration applied to the fingertip (human) or whiskers (rat), increasing stimulus mean speed led to increasing perceived duration. Symmetrically, increasing vibration duration led to increasing perceived intensity. We modeled spike trains from vibrissal somatosensory cortex as input to dual leaky integrators – an intensity integrator with short time constant and a duration integrator with long time constant – generating neurometric functions that replicated the actual psychophysical functions of rats. Returning to human psychophysics, we then confirmed specific predictions of the dual leaky integrator model. This study offers a framework, based on sensory coding and subsequent accumulation of sensory drive, to account for how a feeling of the passage of time accompanies the tactile sensory experience.

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Section: Integration Of Sensory Drive and Alternative Modelssupporting

confidence: 92%

A sensory integration account for time perception

Toso

Fassihi

Paz

et al. 2020

Preprint

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“…Of note, connectivity of the right temporoparietal junction and the right fronto-polar cortex represents both polarity and intensity of affective states. In line with topographies of narrative comprehension and memory encoding revealed in high-order associative regions (Baldassano et al, 2017), our results also demonstrate a chronotopic (Protopapa et al, 2019) organization of affect, where distinct brain areas preferentially track changes in the emotional experience at different timescales, ranging from a few to several minutes. complexity (24% of the explained variance) represents how much the affective state is associated with cognitive processes (positive scores), rather than being characterized by fast and automatic responses (negative scores); (c) intensity (16% of the explained variance) denotes whether the experience is perceived as highly (high positive scores) or mildly (low positive scores) emotional.…”

Section: Introductionsupporting

confidence: 90%

“…Previous studies on memory and narrative comprehension Baldassano et al, 2017;Chen et al, 2016) demonstrated that the brain splits the experience at multiple timescales following a hierarchy in which sensory regions extract information in short segments, whereas high-order areas preferentially encode longer events. We reveal that the same happens for the processing of affect, with chronotopic maps (Protopapa et al, 2019) representing the temporal dynamics of the emotional experience at specific timescales. As compared to studies on narrative comprehension and memory, our results highlight relatively slow dynamics, approximately between 3 and 11 minutes.…”

Section: Discussionmentioning

confidence: 71%

Default and Control networks connectivity dynamics track the stream of affect at multiple timescales

Lettieri

Handjaras

Setti

et al. 2020

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The stream of affect is the result of a constant interaction between past experiences, motivations, expectations and the unfolding of events. How the brain represents the relationship between time and affect has been hardly explored, as it requires modeling the complexity of everyday life in the laboratory. Movies condense into hours a multitude of emotional responses, synchronized across subjects and characterized by temporal dynamics alike real-world experiences.Here, using naturalistic stimulation, time-varying intersubject brain connectivity and behavioral reports, we demonstrate that connectivity strength of large-scale brain networks tracks changes in affect. The default mode network represents the pleasantness of the experience, whereas attention and control networks encode its intensity. Interestingly, these orthogonal descriptions of affect converge in right temporoparietal and fronto-polar cortex. Within these regions, the stream of affect is represented at multiple timescales by chronotopic maps, where connectivity of adjacent areas preferentially maps experiences in 3-to 11-minute segments.--- Figure 3 about here ---

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“…Many animal and human electrophysiology and neuroimaging studies have searched for potential neural regions or putative mechanisms underlying time perception (15,16). This literature finds potential mechanisms in a diverse set of regions including pre-/supplementary motor areas (11,14,17), parietal areas (18,19), insula (20), midbrain dopaminergic neurons (21), and hippocampus and entorhinal cortex (22)(23)(24)(25). The diversity of neural regions apparently associated with human time perception supports the intuition underlying the population clock approach -that the dynamics of a neural system can be interpreted as reflecting time to an external observer because it is dynamic, i.e.…”

Section: Introductionmentioning

confidence: 99%

Trial-by-trial predictions of subjective time from human brain activity

Sherman

Fountas

Seth

et al. 2020

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Author ContributionsWR conceived of the study. MTS and WR designed and pre-registered the experiments and analyses. MTS collected, analyzed, and constructed models of human behavioral and neuroimaging data. ZF constructed the artificial network model and analyzed the data. MTS and WR wrote the manuscript. AKS and ZF provided critical revisions on the manuscript. AbstractHuman experience of time exhibits systematic, context-dependent deviations from objective clock time. For example, time is experienced differently at work than on holiday. The cognitive and neural bases of how time perception interacts with the content of experience remain unclear, and leading explanations of human time perception are not equipped to explain this interaction. We propose an alternative account of human time perception, based on the dynamics of sensory processing. Our approach naturally links content of experience with time perception through a common foundation in basic sensory processing. We provide evidence for this proposal in model-based analyses of the dynamics of perceptual processing in an artificial neural network and in the activity of human sensory cortex. Healthy human participants watched naturalistic, silent videos and estimated their duration while fMRI was acquired. The same videos were used as stimuli for the artificial network.We constructed a computational model that predicted video durations from salient events in the activity of the artificial network, or in participants' visual cortex. The artificial network model reproduced human-like duration estimates, including biases in estimation depending on the content of a given video. Most importantly, the model based on human visual cortex activity reproduced trial-by-trial biases in our human participants' subjective reports, whereas control models trained on auditory or somatosensory activity did not. Together, our results reveal that human subjective time is based on information arising during the processing of our dynamic sensory environment, providing a computational basis for an end-to-end account of time perception. Significance StatementOur perception of time depends on the contents of experience, reflected in expressions such as "a watched pot never boils". Prevailing accounts of human time perception cannot provide good explanations for this. We tested a new explanation: time perception arises from the processing of our dynamic sensory environment. Supporting this theory, human participants' duration reports of silent videos correlated with estimates we reconstructed from activity in the visual cortex of their brain while they watched those videos. This was not a brain-wide phenomenon; reconstructions based on other brain regions did not correlate with subjective reports of duration. Our results validate our new theory, linking content of experience and perception of time through a common foundation in basic sensory processing.

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Chronotopic maps in human supplementary motor area

Cited by 101 publications

References 52 publications

A sensory integration account for time perception

A sensory integration account for time perception

Default and Control networks connectivity dynamics track the stream of affect at multiple timescales

Trial-by-trial predictions of subjective time from human brain activity

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