Spatiotemporal dynamics of similarity-based neural representations of facial identity

Vida, Mark D.; Nestor, Adrian; Plaut, David C.; Behrmann, Marlene

doi:10.1073/pnas.1614763114

Cited by 52 publications

(60 citation statements)

References 50 publications

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“…In ROI analyses we similarly found an early peak in fMRI-EEG correlations in V1, and a later peak in OFA and FFA. Our time trajectories are similar to those reported in a previous MEG study (Vida et al, 2017), which found first peaks for V1, OFA and FFA at around 150 ms and later peaks ~250 ms. Both in our and their results, information in V1 clearly dominated early in time, and later in time, the information from OFA and FFA was relatively more prominent, though mainly not surpassing correlations with V1.…”

Section: Discussionsupporting

confidence: 89%

“…In left OFA, the correlations remained significant until 480 ms. The overall spatio-temporal structure found here was quite similar to that reported earlier in a MEG study (Vida et al, 2017) looking at the coding of face identities in the brain, finding accurate classifications in the left V1 around 150 ms, and relatively higher decoding accuracy for the right LO and the right FG around 250 ms. To ensure that our results were not due to selecting the five most informative voxels, the ROI analyses were repeated using all the voxels within a given BALSA-area. The results were similar except that the right FFA did not correlate significantly with EEG ( Supplementary Figure 3).…”

Section: Combined Eeg-fmri Reveals Spatiotemporal Pattern Of Face Prosupporting

confidence: 86%

“…Coding of identities is usually found later. Although earliest results are found from ~100 ms onwards (Ambrus, Kaiser, Cichy, & Kovács, 2019;Vida, Nestor, Plaut, & Behrmann, 2017), higher-level identity representations surpassing low-level visual information (Vida et al, 2017), as well as sensitivity to familiar faces (Schweinberger & Neumann, 2016), are found later, at around 250 ms, and differentiation of same sex identities only after 400 ms (Ambrus et al, 2019).…”

Section: Introductionmentioning

confidence: 92%

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Spatio-temporal dynamics of face perception

Muukkonen

Ölander

Numminen

et al. 2019

Preprint

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The temporal and spatial neural processing of faces has been investigated rigorously, but few studies have unified these dimensions to reveal the spatio-temporal dynamics postulated by the models of face processing. We used support vector machine decoding and representational similarity analysis to combine information from different locations (fMRI), time windows (EEG), and theoretical models. By correlating information matrices derived from pairwise classifications of neural responses to different facial expressions (neutral, happy, fearful, angry), we found early EEG time windows (starting around 130 ms) to match fMRI data from early visual cortex (EVC), and later time windows (starting around 190ms) to match data from occipital and fusiform face areas (OFA/FFA) and posterior superior temporal sulcus (pSTS).According to model comparisons, the EEG classifications were based more on low-level visual features than expression intensities or categories. In fMRI, the model comparisons revealed change along the processing hierarchy, from low-level visual feature coding in EVC to coding of intensity of expressions in the right pSTS. The results highlight the importance of a multimodal approach for understanding the functional roles of different brain regions in face processing.

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Section: Discussionsupporting

confidence: 89%

Section: Combined Eeg-fmri Reveals Spatiotemporal Pattern Of Face Prosupporting

confidence: 86%

Section: Introductionmentioning

confidence: 92%

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Spatio-temporal dynamics of face perception

Muukkonen

Ölander

Numminen

et al. 2019

Preprint

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“…Fast decoding of object category was achieved at 100 ms from small neuronal populations in primates (Hung & Poggio, 2005) and from invasively recorded responses in human visual cortex (Li & Lu, 2009). Furthermore, recent applications of MVPA to electrophysiological data have resolved face identity processing to early latencies (50-70 ms after stimulus onset; Davidesco et al, 2014;Nemrodov et al, 2016;Vida, Nestor, Plaut, & Behrmann, 2017). In addition to revealing the temporal dynamics of visual processing, multivariate methods have furthered our understanding of the transformations performed by cells in macaque face patches to encode face identity (Chang & Tsao, 2017) and have allowed face reconstruction based on non-invasive neural data in humans (Nemrodov et al, 2018;Nestor, Plaut, & Behrmann, 2016).…”

Section: Introductionmentioning

confidence: 99%

Spatiotemporal dynamics in human visual cortex rapidly encode the emotional content of faces

Dima

Perry

Messaritaki

et al. 2018

Human Brain Mapping

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Recognizing emotion in faces is important in human interaction and survival, yet existing studies do not paint a consistent picture of the neural representation supporting this task. To address this, we collected magnetoencephalography (MEG) data while participants passively viewed happy, angry and neutral faces. Using time‐resolved decoding of sensor‐level data, we show that responses to angry faces can be discriminated from happy and neutral faces as early as 90 ms after stimulus onset and only 10 ms later than faces can be discriminated from scrambled stimuli, even in the absence of differences in evoked responses. Time‐resolved relevance patterns in source space track expression‐related information from the visual cortex (100 ms) to higher‐level temporal and frontal areas (200–500 ms). Together, our results point to a system optimised for rapid processing of emotional faces and preferentially tuned to threat, consistent with the important evolutionary role that such a system must have played in the development of human social interactions.

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“…Six dissimilarity matrix (DMs) models representing three types of information were used to this end: visual properties, character identity, and social relationships (Figure 2). All models were compared to neural distance across two different facial expressions within each character identity (Vida et al, 2016). The primary model of visual properties was the Euclidean distance between responses of the C2 layer of HMAX, which simulates the complex visual cell response to an input image (Riesenhuber and Poggio, 1999).…”

Section: Representational Similarity Analysismentioning

confidence: 99%