Functional mapping of the magnocellular and parvocellular subdivisions of human LGN

Denison, Rachel; Vu, An T.; Yacoub, Essa; Feinberg, David; Silver, Michael

doi:10.1016/j.neuroimage.2014.07.019

Cited by 77 publications

(127 citation statements)

References 74 publications

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“…In this pilot study, we used non-face stimuli, sinusoidal counter-phase flickering gratings biased to engaged the M-pathway (a low-luminance contrast, varying gray-on-gray grating with a low spatial frequency and 15 Hz flicker) and biasing P-pathway (an isoluminant, high color-contrast red-green grating with high spatial frequency with slow, 5 Hz flicker), following the method detailed in Denison et al 84 . These types of stimuli have been known to selectively bias M-pathway and P-pathway processing in previous studies using object, letter, scene, and face stimuli 44,45,50,84–87 . Although different types of stimuli and different cohorts of participants were employed, the localizer scans showed activations in foci adjacent to and overlapping with our ROIs including the bilateral IPS and SFG activated by M-pathway stimuli and the bilateral FG activated by P-pathway stimuli.…”

Section: Resultsmentioning

confidence: 99%

Differential hemispheric and visual stream contributions to ensemble coding of crowd emotion

Albohn

Steiner

et al. 2017

Nat Hum Behav

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In crowds, where scrutinizing individual facial expressions is inefficient, humans can make snap judgments about the prevailing mood by reading “crowd emotion”. We investigated how the brain accomplishes this feat in a set of behavioral and fMRI studies. Participants were asked to either avoid or approach one of two crowds of faces presented in the left and right visual hemifields. Perception of crowd emotion was improved when crowd stimuli contained goal-congruent cues and was highly lateralized to the right hemisphere. The dorsal visual stream was preferentially activated in crowd emotion processing, with activity in the intraparietal sulcus and superior frontal gyrus predicting perceptual accuracy for crowd emotion perception, whereas activity in the fusiform cortex in the ventral stream predicted better perception of individual facial expressions. Our findings thus reveal significant behavioral differences and differential involvement of the hemispheres and the major visual streams in reading crowd versus individual face expressions.

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Section: Resultsmentioning

confidence: 99%

Differential hemispheric and visual stream contributions to ensemble coding of crowd emotion

Albohn

Steiner

et al. 2017

Nat Hum Behav

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“…P cells are responsible for virtually all colour processing. In a nutshell, M cells have high temporal acuity but poor spatial acuity, whereas P cells have high spatial acuity but poor temporal acuity (Denison et al, 2014;Derrington and Lennie, 1984;Legge, 1978;Livingstone and Hubel, 1988). In real-world vision, both M and P cells collaborate to create and update our dynamic conscious perception of objects and scenes.…”

Section: Magnocellular Neuron (M-cell) Enhancement Theorymentioning

confidence: 99%

Altered visual perception near the hands: A critical review of attentional and neurophysiological models

Goodhew

Edwards

Ferber

et al. 2015

Neuroscience & Biobehavioral Reviews

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Visual perception changes as a function of hand proximity. While various theoretical accounts have been offered for this alteration (attentional prioritisation, bimodal cell involvement, detailed evaluation, and magnocellular neuron input enhancement), the current literature lacks consensus on these mechanisms. The purpose of this review, therefore, is to critically review the existing body of literature in light of these distinct theoretical accounts. We find that a growing number of results support the magnocellular (M-cell) enhancement account, and are difficult to reconcile with general attention-based explanations. Despite this key theoretical development in the field, there has been some ambiguity with interpretations offered in recent papers, for example, equating the existing attentional and M-cell based explanations, when in fact they make contrasting predictions. We therefore highlight the differential predictions arising from the distinct theoretical accounts. Importantly, however, we also offer novel perspectives that synthesises the role of attention and neurophysiological mechanisms in understanding altered visual perception near the hands. We envisage that this theoretical development will ensure that the field can progress from documenting behavioural differences, to a consensus on the underlying visual and neurophysiological mechanisms.

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“…In other words, each M cell encodes information from a relatively large region of a visual scene, and across this region they process coarse spatial Bgist,^and their responses are sharp and precise across time. In technical terms, P cells are especially sensitive to rapid changes in luminance across space (i.e., high spatial frequencies) and slow changes in luminance across time (i.e., low temporal frequencies), whereas M cells are suited to processing slow changes in luminance across space (i.e., low spatial frequencies) and are sensitive to rapid changes in luminance across time (i.e., high temporal frequencies) (Denison, Vu, Yacoub, Feinberg, & Silver, 2014;Derrington & Lennie, 1984;Livingstone & Hubel, 1988;Schiller & Logothetis, 1990).…”

mentioning

confidence: 99%

Testing the generality of the zoom-lens model: Evidence for visual-pathway specific effects of attended-region size on perception

Goodhew

Lawrence

Edwards

2017

Atten Percept Psychophys

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There are volumes of information available to process in visual scenes. Visual spatial attention is a critically important selection mechanism that prevents these volumes from overwhelming our visual system's limited-capacity processing resources. We were interested in understanding the effect of the size of the attended area on visual perception. The prevailing model of attended-region size across cognition, perception, and neuroscience is the zoom-lens model. This model stipulates that the magnitude of perceptual processing enhancement is inversely related to the size of the attended region, such that a narrow attended-region facilitates greater perceptual enhancement than a wider region. Yet visual processing is subserved by two major visual pathways (magnocellular and parvocellular) that operate with a degree of independence in early visual processing and encode contrasting visual information. Historically, testing of the zoomlens has used measures of spatial acuity ideally suited to parvocellular processing. This, therefore, raises questions about the generality of the zoom-lens model to different aspects of visual perception. We found that while a narrow attended-region facilitated spatial acuity and the perception of high spatial frequency targets, it had no impact on either temporal acuity or the perception of low spatial frequency targets. This pattern also held up when targets were not presented centrally. This supports the notion that visual attendedregion size has dissociable effects on magnocellular versus parvocellular mediated visual processing.

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Functional mapping of the magnocellular and parvocellular subdivisions of human LGN

Cited by 77 publications

References 74 publications

Differential hemispheric and visual stream contributions to ensemble coding of crowd emotion

Differential hemispheric and visual stream contributions to ensemble coding of crowd emotion

Altered visual perception near the hands: A critical review of attentional and neurophysiological models

Testing the generality of the zoom-lens model: Evidence for visual-pathway specific effects of attended-region size on perception

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