Illusory Contours over Pathological Retinal Scotomas

Elisa De Stefani,Clara Casco,Gianluca Campana,Giuseppe Lo Giudice,Monica Mazzarolo,Luisa Pinello,Chris I Baker

doi:10.1371/journal.pone.0026154

Elisa De Stefani, Clara Casco + Show 5 more

Open Access

https://doi.org/10.1371/journal.pone.0026154

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Journal: PloS one	Publication Date: Oct 12, 2011
Citations: 59	License type: CC BY 4.0

Affiliation: University of Parma, University of Padua

Abstract

Our visual percepts are not fully determined by physical stimulus inputs. Thus, in visual illusions such as the Kanizsa figure, inducers presented at the corners allow one to perceive the bounding contours of the figure in the absence of luminance-defined borders. We examined the discrimination of the curvature of these illusory contours that pass across retinal scotomas caused by macular degeneration. In contrast with previous studies with normal-sighted subjects that showed no perception of these illusory contours in the region of physiological scotomas at the optic nerve head, we demonstrated perfect discrimination of the curvature of the illusory contours over the pathological retinal scotoma. The illusion occurred despite the large scar around the macular lesion, strongly reducing discrimination of whether the inducer openings were acute or obtuse and suggesting that the coarse information in the inducers (low spatial frequency) sufficed. The result that subjective contours can pass through the pathological retinal scotoma suggests that the visual cortex, despite the loss of bottom-up input, can use low-spatial frequency information from the inducers to form a neural representation of new complex geometrical shapes inside the scotoma.

Highlights

Chi square with Yates correction [32] revealed that the threshold of each juvenile macular degeneration (JMD) subjects never significantly differed from observed thresholds in the control group (JMD1: x2 = 4.4, P = 0.51; JMD2: x2 = 4.7, P = 0.45; JMD3: x2 = 4.11, P = 0.53)
Except for JMD3, who had some residual vision in the right eye, JMD1 and JMD2 were incapable of performing the task and behaved at chance regardless of angle size
Chi square with Yates correction revealed that the threshold of two JMD subjects significantly differed from observed thresholds in the control group (JMD1, x2 = 12.4, P = 0.03 and JMD2, x2 = 13.7, P = 0.02)

Summary

Introduction

Filling-in has been known for many years in normal-sighted subjects, in physiological scotomas at the optic nerve head [2], and in the artificial scotoma produced by a small region of uniform luminance surrounded by a structured background [3]. It is currently debated whether perceptual filling-in is caused by active neural processes, i.e., activity in visual areas, or whether there is no need for the neural representation of the surface region where the filling-in of visual features is perceived [4,5,6,7]. An often-debated issue is whether different mechanisms underlie filling-in at the optic nerve head and at scotomas [20,21]

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