皮层中水平视觉形状加工的意义和意义

IF 2.6 3区 心理学 Q2 PSYCHOLOGY
B. Breitmeyer
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引用次数: 1

摘要

幸运的是,我们很少对世界产生误解。只有在高度人造的实验室环境中,它们才会经常发生;或者在非常罕见的人类病例中,它们会持续出现。不管怎样,这些关于刺激的呈现和在意识中的视觉记录之间的处理层次的误解都可以获得有价值的信息。Vannuscorps等人(2021)对Davida对2D刺激的误解进行了一个有趣的案例研究,该研究揭示了视觉皮层在纹状层对基本视觉特征的无意识登记和对刺激的知觉、有意识登记之间发生了什么,这种知觉依赖于纹状层后处理的多个分布区域的神经活动的整合。Vannuscorps等人提出(a)从最初的视黄网膜重建独立的二维有界视觉空间区域开始,后纹状体中间皮质水平(b)额外构建相应的视觉刺激的中间形状中心表征(iscr),所有这些(c)都在无意识的加工水平。该建议是非常合理的,为视觉场景感知的研究提供了丰富的途径。此外,它与理论和实证研究的几条路线是一致的。在理论方面,Stephen Grossberg提出了越来越复杂的视觉感知理论模型(引用于Grossberg, 2016),这些模型揭示了Vannuscorps等人主要关注的中间皮层处理水平-高达V4。在早期皮层处理中,原始特征(亮度对比、颜色、方向、大小等)的配准是在iscr上进行的,随后是视野中有界的二维区域的分离。在Grossberg模型中,2-D有界区域是边界轮廓系统(BCS)和填充其表面属性(如特定灰度)的特征轮廓系统(FCS)相互作用的结果。边界轮廓系统(BCS)划定了有界区域的轮廓,例如矩形。探索恒河猴的皮层层次,Felleman和同事(Felleman et al., 1997;Wang et al., 2007;Xiao et al., 1999)研究了轮廓(例如,方向)和表面特性(例如,颜色,亮度)的处理是如何在分离的皮质模块中进行的,从早期的V1水平到中间(V2)和更高(V4)的层次。由于类似的加工过程很可能发生在人类身上,所以Felleman等人的工作为Vannuscorps等人提出的ISCR加工过程的本质提供了重要的线索。Grossberg(2003)在他的章节“填充形式:视觉皮层中的表面和边界相互作用”中提出,表面是用来观看的。换句话说,看到或感知,对分离的二维形状的有意识登记-以及后来的三维形状-只能在表面填充过程开始后发生。Breitmeyer和Jacob(2012)研究了刺激表面特征的实时填充过程是如何发生的。正如Vannuscorps等人提出的那样,形式或形状本身可以完全在无意识的ISCR加工水平上进行加工。这方面的经验证据来自各种隐性启动研究,在这些研究中,启动形状的处理仅限于无意识水平。例如,Breitmeyer等人(2005)比较了整个方形刺激和菱形刺激的启动效应,只比较了它们的顶点/角和侧面。当整个启动被掩盖时,启动效应最强,略弱
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Significance and implications of visual shape processing at intermediate cortical levels
It is our fortune that misperceptions of the world are very rare. Only in highly contrived laboratory settings do they occur regularly; or in very rare human cases do they show up consistently. Either way, valuable information can be garnered from these misperceptions about the hierarchical levels of processing that occur between the presentation of a stimulus and its visual registration in consciousness. Vannuscorps et al. (2021) present an intriguing case study of Davida’s misperceptions of 2D stimuli that shed light on what happens in the visual cortex between the unconscious registration of basic visual features at the striate level and the perception, the conscious registration, of the stimulus that relies on the integration of neural activity in multiple and distributed areas of post-striate processing. Vannuscorps et al. propose that (a) from an initial retinotopic construction of separate 2D bounded regions of visual space, the post-striate, intermediate cortical levels (b) additionally construct correspondingly intermediate shape-centered representations (ISCRs) of visual stimuli, and all this (c) at unconscious levels of processing. The proposal is very reasonable and offers fruitful avenues of research of visual scene perception. Moreover, it is consistent with several lines of theoretical and empirical research. As to theory, Stephen Grossberg has presented increasingly sophisticated theoretical models of visual perception (cited in Grossberg, 2016) which shed light on the intermediate cortical levels of processing – up to V4 – that are of primary concern to Vannuscorps et al. The registration of primitive features (brightness contrast, colour, orientation, size, etc.) in early cortical processing is followed at the ISCRs by the segregation of bounded 2-D regions of the visual field. In the Grossberg model, 2-D bounded regions result from the interaction of the boundary-contour system (BCS) delimiting the contours of a bounded region, e.g., a rectangle, and the feature-contour system (FCS) that fills in its surface properties, say a particular grey level. Exploring the cortical hierarchy in rhesus monkey, Felleman and coworkers (Felleman et al., 1997; Wang et al., 2007; Xiao et al., 1999) have investigated how the processing of contour (e.g., orientation) and surface properties (e.g., colour, brightness) proceeds in segregated cortical modules from early V1 levels to intermediate (V2) and higher (V4) levels of the hierarchy. Since similar processing most likely occurs in humans, Felleman et al.’s work sheds important light on the nature of Vannuscorps et al.’s proposed ISCR processing. In his chapter “Filling-in the forms: Surface and boundary interactions in visual cortex” Grossberg (2003) suggested that surfaces are for seeing. In other words, seeing or perception, the conscious registration of the segregated two-dimensional shapes – and the later three-dimensional ones – can occur only as and after the surface filling-in process initiated. How real-time filling-in processes of a stimulus’s surface features can occur has been investigated by Breitmeyer and Jacob (2012). The form or shape itself, can be processed entirely at the unconscious ISCR levels of processing, as Vannuscorps et al. propose. Empirical evidence for this comes from a variety of masked priming studies in which processing of the prime shape is confined to unconscious levels. For instance, Breitmeyer et al. (2005) compared the priming effects of entire square and rhombic stimuli, their vertices/corners only, and their sides only. The strongest priming effects were obtained when entire primes were masked, somewhat weaker
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来源期刊
Cognitive Neuropsychology
Cognitive Neuropsychology 医学-心理学
CiteScore
5.50
自引率
11.80%
发文量
23
审稿时长
>12 weeks
期刊介绍: Cognitive Neuropsychology is of interest to cognitive scientists and neuroscientists, neuropsychologists, neurologists, psycholinguists, speech pathologists, physiotherapists, and psychiatrists.
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