A sensory memory to preserve visual representations across eye movements

Akbarian, Amir; Clark, Kelsey; Noudoost, Behrad; Nategh, Neda

doi:10.1038/s41467-021-26756-0

Cited by 7 publications

(13 citation statements)

References 67 publications

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“…The classical GLM has been widely used for encoding and decoding neural responses in low-level visual areas (such as the retina, LGN, and V1) 62,63 , but they fall short in capturing the time-varying characteristics of higher-level visual areas. To model responses in these areas, nonstationary model frameworks that enables a time-varying extension of a GLM have been developed, which showed success in characterizing the perisaccadic spatiotemporal changes of neural response and reading out perisaccadic stimulus information on the same timescale of saccadic eye movements 42,49,64,65 . In the present study, we took advantage of this GLM framework (SVGLM) and developed a procedure to measure spatial bias based on instantaneous neural sensitivity at various locations to identify the neural components contributing to spatial bias.…”

Section: Discussionmentioning

confidence: 99%

“…By quantifying the statistical dependencies of spiking responses on several behavioral (e.g., eye movement) or external (e.g., visual stimuli) variables, however, point process statistical models provide a powerful means to capture the encoding and decoding of visual information as continuously varying with eye movements, with no assumption on the function of neurons. To investigate the neural basis of perisaccadic mislocalization, this study used a time-varying generalized linear model framework capable of capturing the fast spatiotemporal dynamics of neural sensitivity around the time of saccades 42,49 , and examine the link between perisaccadic visual responses and visuospatial perception.…”

Section: Introductionmentioning

confidence: 99%

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Neural correlates of perisaccadic visual mislocalization in extrastriate cortex

Weng,

Akbarian,

Clark

et al. 2023

Preprint

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When interacting with the visual world using saccadic eye movements (saccades), the perceived location of visual stimuli becomes biased, a phenomenon called perisaccadic mislocalization, which is indeed an exemplar of the brain’s dynamic representation of the visual world. However, the neural mechanism underlying this altered visuospatial perception and its potential link to other perisaccadic perceptual phenomena have not been established. Using a combined experimental and computational approach, we were able to quantify spatial bias around the saccade target (ST) based on the perisaccadic dynamics of extrastriate spatiotemporal sensitivity captured by statistical models. This approach could predict the perisaccadic spatial bias around the ST, consistent with the psychophysical studies, and revealed the precise neuronal response components underlying representational bias. These findings also established the crucial role of response remapping toward ST representation for neurons with receptive fields far from the ST in driving the ST spatial bias. Moreover, we showed that, by allocating more resources for visual target representation, visual areas enhance their representation of the ST location, even at the expense of transient distortions in spatial representation. This potential neural basis for perisaccadic ST representation, also supports a general role for extrastriate neurons in creating the perception of stimulus location.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Neural correlates of perisaccadic visual mislocalization in extrastriate cortex

Weng,

Akbarian,

Clark

et al. 2023

Preprint

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“…Each approach mentioned above has its own pros and cons, but few of them can succeed in capturing the responses of neurons in the higher visual areas where multiplexed neural signals reflecting the interaction of sensory and non-sensory variables complicate the neural code ( Table 1 ). One such example is saccadic eye movements, which involve fast and complex modulations in neuronal sensitivity in the extrastriate visual areas and prefrontal cortex during the perisaccadic period ( Nakamura and Colby, 2002 ; Sommer and Wurtz, 2006 ; Zirnsak et al, 2011 , 2014 ; Neupane et al, 2016 , 2020 ; Niknam et al, 2019 ; Akbarian et al, 2021 ). Quantitatively characterizing the perisaccadic sensitivity modulations on the fast timescale of saccades is critical for understanding the neural basis of various perisaccadic perceptual phenomena.…”

Section: Glm-based Approaches For Nonstationary Responsesmentioning

confidence: 99%

“…Saccade experiments and saccade-related visual behavior stand as a potent and classical paradigm in visual neuroscience, serving as a robust tool to establish links between neural responses and behavior or cognition ( Honda, 1989 ; Nakamura and Colby, 2002 ; Awater and Lappe, 2004 ; Jeffries et al, 2007 ; Zirnsak et al, 2011 ; Irwin and Robinson, 2015 ; Wurtz, 2018 ). Saccade paradigms have been implemented to unravel the intricate physiological and circuit mechanisms underlying various cognitive processes, including visual perception, attention, memory, and more ( Deubel and Schneider, 1996 ; Ross et al, 1997 ; Friston et al, 2012 ; Cronin and Irwin, 2018 ; Edwards et al, 2018 ; Akbarian et al, 2021 ).…”

Section: Introductionmentioning

confidence: 99%

Time-varying generalized linear models: characterizing and decoding neuronal dynamics in higher visual areas

Weng,

Clark,

Akbarian

et al. 2024

Front. Comput. Neurosci.

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To create a behaviorally relevant representation of the visual world, neurons in higher visual areas exhibit dynamic response changes to account for the time-varying interactions between external (e.g., visual input) and internal (e.g., reward value) factors. The resulting high-dimensional representational space poses challenges for precisely quantifying individual factors’ contributions to the representation and readout of sensory information during a behavior. The widely used point process generalized linear model (GLM) approach provides a powerful framework for a quantitative description of neuronal processing as a function of various sensory and non-sensory inputs (encoding) as well as linking particular response components to particular behaviors (decoding), at the level of single trials and individual neurons. However, most existing variations of GLMs assume the neural systems to be time-invariant, making them inadequate for modeling nonstationary characteristics of neuronal sensitivity in higher visual areas. In this review, we summarize some of the existing GLM variations, with a focus on time-varying extensions. We highlight their applications to understanding neural representations in higher visual areas and decoding transient neuronal sensitivity as well as linking physiology to behavior through manipulation of model components. This time-varying class of statistical models provide valuable insights into the neural basis of various visual behaviors in higher visual areas and hold significant potential for uncovering the fundamental computational principles that govern neuronal processing underlying various behaviors in different regions of the brain.

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“…Furthermore, while work in human psychophysics has confirmed that remapping preserves some 17,23 but perhaps not all 24 visual feature selectivity at the level of perception, whether feature selectivity is preserved in individual neurons as they remap remains an open question. Indeed, despite extensive study, much remains unknown about the properties and extent of receptive field remapping, in large part due to limitations of the spatiotemporal resolution at which the phenomenon was studied [25][26][27][28] .…”

Section: Introductionmentioning

confidence: 99%

Widespread Receptive Field Remapping in Early Visual Cortex

Denagamage

Morton

Nandy

2023

Preprint

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Our eyes are in constant motion, yet we perceive the visual world as being stable. Predictive remapping of receptive fields is thought to be one of the critical mechanisms for enforcing perceptual stability during eye movements. While receptive field remapping has been identified in several cortical areas, the spatiotemporal dynamics of remapping, and its consequences on the tuning properties of neurons, remain poorly understood. Here, we tracked remapping receptive fields in hundreds of neurons from visual Area V2 while subjects performed a cued saccade task. We found that remapping was far more widespread in Area V2 than previously reported and can be found in neurons from all recorded neural populations in the laminar cortical circuit. Surprisingly, neurons undergoing remapping exhibit sensitivity to two punctate locations in visual space. Remapping is also accompanied by a transient sharpening of orientation tuning. Taken together, these results shed light on the spatiotemporal dynamics of remapping and its ubiquitous prevalence in the early visual cortex, and force us to revise current models of perceptual stability.

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A sensory memory to preserve visual representations across eye movements

Cited by 7 publications

References 67 publications

Neural correlates of perisaccadic visual mislocalization in extrastriate cortex

Neural correlates of perisaccadic visual mislocalization in extrastriate cortex

Time-varying generalized linear models: characterizing and decoding neuronal dynamics in higher visual areas

Widespread Receptive Field Remapping in Early Visual Cortex

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