Visual magnocellular and structure from motion perceptual deficits in a neurodevelopmental model of dorsal stream function

Mafalda Mendes , Fátima Silva , Luísa Simões , Marta Jorge , Jorge Saraiva , Miguel Castelo-Branco
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引用次数: 35

Abstract

Williams syndrome (WS) is a neurodevelopmental disorder of genetic origin that has been used as a model to understand visual cognition. We have investigated early deficits in the afferent magnocellular pathway and their relation to abnormal visual dorsal processing in WS. A spatiotemporal contrast sensitivity task that is known to selectively activate that pathway was used in six WS subjects. Additionally, we have compared visual performance in 2D and 3D motion integration tasks. A novel 3D motion coherence task (using spheres with unpredictable axis of rotation) was used in order to investigate possible impairment of occipitoparietal areas that are known to be involved in 3D structure from motion (SFM) perception. We have found a significant involvement of low-level magnocellular maps in WS as assessed by the contrast sensitivity task. On the contrary, no significant differences were observed between WS and the control groups in the 2D motion integration tasks. However, all WS subjects were significantly impaired in the 3D SFM task. Our findings suggest that magnocellular damage may occur in addition to dorsal stream deficits in these patients. They are also consistent with recently described genetic and neuroanatomic abnormalities in retinotopic visual areas. Finally, selective SFM coherence deficits support the proposal that there is a specific pathway in the dorsal stream that is involved in motion processing of 3D surfaces, which seems to be impaired in this disorder.

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背流功能的神经发育模型中运动知觉缺陷的视觉大细胞和结构
威廉姆斯综合征(WS)是一种遗传来源的神经发育障碍,已被用作理解视觉认知的模型。我们研究了传入大细胞通路的早期缺陷及其与WS中视觉背侧加工异常的关系。在6名WS受试者中使用了一项已知可选择性激活该通路的时空对比敏感性任务。此外,我们还比较了2D和3D运动集成任务的视觉表现。一种新颖的3D运动一致性任务(使用具有不可预测旋转轴的球体)用于研究已知参与3D运动结构(SFM)感知的枕顶叶区域可能的损伤。我们发现通过对比敏感度任务评估的低水平巨细胞图在WS中的显著参与。相反,在2D运动整合任务中,WS组与对照组之间没有显著差异。然而,所有WS受试者在3D SFM任务中都明显受损。我们的研究结果表明,在这些患者中,除了背流缺陷外,还可能发生大细胞损伤。它们也与最近描述的视网膜异位视觉区域的遗传和神经解剖学异常一致。最后,选择性SFM一致性缺陷支持了背流中参与3D表面运动加工的特定通路的建议,该通路似乎在这种疾病中受损。
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