Cortical Dynamics Subserving Visual Apparent Motion

Ahmed, Bashir; Hanazawa, Akitoshi; Undeman, Calle; Eriksson, David; Valentiniene, Sonata; Roland, Per E.

doi:10.1093/cercor/bhn038

Cited by 58 publications

(94 citation statements)

References 65 publications

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“…Feedback from higher-level visual areas to V1 seems a likely explanation for the effects of stimulus predictability reported here as these areas have larger receptive fields than V1, allowing them to determine the trajectory of long-range apparent motion (Angelucci and Bullier, 2003, Angelucci and Bressloff, 2006, Ichida et al, 2007. This fact, taken together with the observation that during long-range apparent motion hMT/V5ϩ sends feedback signals to V1 (Muckli et al, 2005;Sterzer et al, 2006;Ahmed et al, 2008;Wibral et al, 2008), can be considered a strong indication that activation in hMT/ V5ϩ drives the predictability effect in V1. However, several studies have suggested that local processing of feedforward signals in V1 allows for more sophisticated neural computations than one would expect from classical receptive field models (Seriès et al, 2002(Seriès et al, , 2003Masland and Martin, 2007).…”

Section: Discussionmentioning

confidence: 52%

Stimulus Predictability Reduces Responses in Primary Visual Cortex

Alink¹,

Schwiedrzik²,

Kohler³

et al. 2010

J. Neurosci.

425

398

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In this functional magnetic resonance imaging study we tested whether the predictability of stimuli affects responses in primary visual cortex (V1). The results of this study indicate that visual stimuli evoke smaller responses in V1 when their onset or motion direction can be predicted from the dynamics of surrounding illusory motion. We conclude from this finding that the human brain anticipates forthcoming sensory input that allows predictable visual stimuli to be processed with less neural activation at early stages of cortical processing.

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Section: Discussionmentioning

confidence: 52%

Stimulus Predictability Reduces Responses in Primary Visual Cortex

Alink¹,

Schwiedrzik²,

Kohler³

et al. 2010

J. Neurosci.

425

398

View full text Add to dashboard Cite

show abstract

“…These brain regions are activated differentially, depending upon the given task at hand and the specific type(s) of cognition necessary to address it [60][61][62]. The prefrontal cortex is activated by all tasks, which likely reflects its primary role in the organization of thought.…”

Section: Expertise Giftedness Prodigy Intelligence-definitionsmentioning

confidence: 99%

Adaptation, Expertise, and Giftedness: Towards an Understanding of Cortical, Subcortical, and Cerebellar Network Contributions

Koziol¹,

Budding

Chidekel

2010

Cerebellum

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Current cortico-centric models of cognition lack a cohesive neuroanatomic framework that sufficiently considers overlapping levels of function, from "pathological" through "normal" to "gifted" or exceptional ability. While most cognitive theories presume an evolutionary context, few actively consider the process of adaptation, including concepts of neurodevelopment. Further, the frequent co-occurrence of "gifted" and "pathological" function is difficult to explain from a cortico-centric point of view. This comprehensive review paper proposes a framework that includes the brain's vertical organization and considers "giftedness" from an evolutionary and neurodevelopmental vantage point. We begin by discussing the current cortico-centric model of cognition and its relationship to intelligence. We then review an integrated, dual-tiered model of cognition that better explains the process of adaptation by simultaneously allowing for both stimulus-based processing and higher-order cognitive control. We consider the role of the basal ganglia within this model, particularly in relation to reward circuitry and instrumental learning. We review the important role of white matter tracts in relation to speed of adaptation and development of behavioral mastery. We examine the cerebellum's critical role in behavioral refinement and in cognitive and behavioral automation, particularly in relation to expertise and giftedness. We conclude this integrated model of brain function by considering the savant syndrome, which we believe is best understood within the context of a dual-tiered model of cognition that allows for automaticity in adaptation as well as higher-order executive control.

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“…This does not seem to be the case, as sub-threshold dV m (t)/dt increases very well may influence the subsequent dynamics of a neuron population both in single cortical neurons and at the mesoscopic neuron network scale. Indeed such dV m (t)/dt increases can be induced by neurons in other cortical areas Ahmed et al, 2008;Harvey et al, 2009;Niell and Stryker, 2010;Roland, 2010;Harvey and Roland, 2013;Zagha et al, 2013).…”

Section: Background and Scopementioning

confidence: 99%

“…Part of the explanation might be that the dye signal in vivo reflects synaptic activity at the mesoscopic scale, whereas the action potential recordings capture the activity of single neurons (Lippert et al, 2007;Eriksson et al, 2008). Nevertheless, in several studies one can follow how net increases in the synaptic activity propagate over the cortical areas when the cortex is perturbed by a sensory transient (Senseman, 1996;Prechtl et al, 1997;Senseman and Robbins, 2002;Slovin et al, 2002;Grinvald and Hildseheim, 2004;Roland et al, 2006;Ferezou et al, 2007;Lippert et al, 2007;Xu et al, 2007;Ahmed et al, 2008;Han et al, 2008;Takagaki et al, 2008;Yoshida et al, 2008;Harvey et al, 2009;Ayzenshtat et al, 2010;Meirovithz et al, 2010;Ng et al, 2010;Polack and Contreras, 2012;Harvey and Roland, 2013). This synaptic dynamics may show some order in the feed-forward propagation of net-excitation for example between V1 and V2 in monkeys, rats and turtles, between the barrel field and the motor cortex in the mouse, and between visual areas 17, 18 and 19, 21 in the ferret.…”

Section: Frontiers In Systemsmentioning

confidence: 99%

“…Some of these studies contain observations of a reverse order of synaptic propagation, that is, from higher areas towards the primary sensory areas, some 40-50 ms later, i.e., 80-100 ms after the stimulus onset Lippert et al, 2007;Xu et al, 2007;Ahmed et al, 2008;Takagaki et al, 2008;Yoshida et al, 2008;Harvey et al, 2009;Ayzenshtat et al, 2010;Ng et al, 2010;Lim et al, 2012; see also Zheng and Yao, 2012;Harvey and Roland, 2013). This mode of propagation has been named feedback.…”

Section: Frontiers In Systemsmentioning

confidence: 99%

See 1 more Smart Citation

Cortico-cortical Communication Dynamics

2014

Frontiers Research Topics

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In principle, cortico-cortical communication dynamics is simple: neurons in one cortical area communicate by sending action potentials that release glutamate and excite their target neurons in other cortical areas. In practice, knowledge about cortico-cortical communication dynamics is minute. One reason is that no current technique can capture the fast spatio-temporal cortico-cortical evolution of action potential transmission and membrane conductances with sufficient spatial resolution. A combination of optogenetics and monosynaptic tracing with virus can reveal the spatio-temporal cortico-cortical dynamics of specific neurons and their targets, but does not reveal how the dynamics evolves under natural conditions. Spontaneous ongoing action potentials also spread across cortical areas and are difficult to separate from structured evoked and intrinsic brain activity such as thinking. At a certain state of evolution, the dynamics may engage larger populations of neurons to drive the brain to decisions, percepts and behaviors. For example, successfully evolving dynamics to sensory transients can appear at the mesoscopic scale revealing how the transient is perceived. As a consequence of these methodological and conceptual difficulties, studies in this field comprise a wide range of computational models, large-scale measurements (e.g., by MEG, EEG), and a combination of invasive measurements in animal experiments. Further obstacles and challenges of studying cortico-cortical communication dynamics are outlined in this critical review.

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Cortical Dynamics Subserving Visual Apparent Motion

Cited by 58 publications

References 65 publications

Stimulus Predictability Reduces Responses in Primary Visual Cortex

Stimulus Predictability Reduces Responses in Primary Visual Cortex

Adaptation, Expertise, and Giftedness: Towards an Understanding of Cortical, Subcortical, and Cerebellar Network Contributions

Cortico-cortical Communication Dynamics

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