Adrian Nestor scite author profile

Face individuation is one of the most impressive achievements of our visual system, and yet uncovering the neural mechanisms subserving this feat appears to elude traditional approaches to functional brain data analysis. The present study investigates the neural code of facial identity perception with the aim of ascertaining its distributed nature and informational basis. To this end, we use a sequence of multivariate pattern analyses applied to functional magnetic resonance imaging (fMRI) data. First, we combine information-based brain mapping and dynamic discrimination analysis to locate spatiotemporal patterns that support face classification at the individual level. This analysis reveals a network of fusiform and anterior temporal areas that carry information about facial identity and provides evidence that the fusiform face area responds with distinct patterns of activation to different face identities. Second, we assess the information structure of the network using recursive feature elimination. We find that diagnostic information is distributed evenly among anterior regions of the mapped network and that a right anterior region of the fusiform gyrus plays a central role within the information network mediating face individuation. These findings serve to map out and characterize a cortical system responsible for individuation. More generally, in the context of functionally defined networks, they provide an account of distributed processing grounded in information-based architectures.T he neural basis of face perception is the focus of extensive research as it provides key insights both into the computational architecture of visual recognition (1, 2) and into the functional organization of the brain (3). A central theme of this research emphasizes the distribution of face processing across a network of spatially segregated areas (4-10). However, there remains considerable disagreement about how information is represented and processed within this network to support tasks such as individuation, expression analysis, or high-level semantic processing.One influential view proposes an architecture that maps different tasks to distinct, unique cortical regions (6) and, as such, draws attention to the specificity of this mapping (11)(12)(13)(14)(15)(16)(17)(18)(19)(20). As a case in point, face individuation (e.g., differentiating Steve Jobs from Bill Gates across changes in expression) is commonly mapped onto the fusiform face area (FFA) (6, 21). Although recent studies have questioned this role of the FFA (14, 15), overall they agree with this task-based architecture as they single out other areas supporting individuation.However, various distributed accounts have also been considered. One such account ascribes facial identity processing to multiple, independent regions. Along these lines, the FFA's sensitivity to individuation has been variedly extended to areas of the inferior occipital gyrus (5), the superior temporal sulcus (12), and the temporal pole (22). An alternative scenario is that identity is encode...

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The time course of individual face recognition: A pattern analysis of ERP signals

Nemrodov

Niemeier

Mok

et al. 2016

NeuroImage

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An extensive body of work documents the time course of neural face processing in the human visual cortex. However, the majority of this work has focused on specific temporal landmarks, such as N170 and N250 components, derived through univariate analyses of EEG data. Here, we take on a broader evaluation of ERP signals related to individual face recognition as we attempt to move beyond the leading theoretical and methodological framework through the application of pattern analysis to ERP data. Specifically, we investigate the spatiotemporal profile of identity recognition across variation in emotional expression. To this end, we apply pattern classification to ERP signals both in time, for any single electrode, and in space, across multiple electrodes. Our results confirm the significance of traditional ERP components in face processing. At the same time though, they support the idea that the temporal profile of face recognition is incompletely described by such components. First, we show that signals associated with different facial identities can be discriminated from each other outside the scope of these components, as early as 70ms following stimulus presentation. Next, electrodes associated with traditional ERP components as well as, critically, those not associated with such components are shown to contribute information to stimulus discriminability. And last, the levels of ERP-based pattern discrimination are found to correlate with recognition accuracy across subjects confirming the relevance of these methods for bridging brain and behavior data. Altogether, the current results shed new light on the fine-grained time course of neural face processing and showcase the value of novel methods for pattern analysis to investigating fundamental aspects of visual recognition.

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The Neural Dynamics of Facial Identity Processing: Insights from EEG-Based Pattern Analysis and Image Reconstruction

Nemrodov

Niemeier

Patel

et al. 2018

eNeuro

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Uncovering the neural dynamics of facial identity processing along with its representational basis outlines a major endeavor in the study of visual processing. To this end, here, we record human electroencephalography (EEG) data associated with viewing face stimuli; then, we exploit spatiotemporal EEG information to determine the neural correlates of facial identity representations and to reconstruct the appearance of the corresponding stimuli. Our findings indicate that multiple temporal intervals support: facial identity classification, face space estimation, visual feature extraction and image reconstruction. In particular, we note that both classification and reconstruction accuracy peak in the proximity of the N170 component. Further, aggregate data from a larger interval (50–650 ms after stimulus onset) support robust reconstruction results, consistent with the availability of distinct visual information over time. Thus, theoretically, our findings shed light on the time course of face processing while, methodologically, they demonstrate the feasibility of EEG-based image reconstruction.

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Adrian Nestor

Unraveling the distributed neural code of facial identity through spatiotemporal pattern analysis

The time course of individual face recognition: A pattern analysis of ERP signals

The Neural Dynamics of Facial Identity Processing: Insights from EEG-Based Pattern Analysis and Image Reconstruction

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