利用多模态磁共振成像技术研究人类双目视觉系统。

IF 1.6 4区 心理学 Q3 OPHTHALMOLOGY
Holly Bridge, Ifan Betina Ip, Andrew J Parker
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引用次数: 0

摘要

动物(包括人类)拥有两只面向前方、视角略有不同的眼睛,这使它们能够区分深度上的细微差异(差异),从而促进与世界的互动。双眼视觉系统开始于初级视觉皮层,因为这是来自眼睛的信息第一次被整合的地方。磁共振成像(MRI)是非侵入性研究该系统的理想工具,因为它可以提供一系列关于人脑结构、功能、神经化学和连通性的详细测量。由于双眼视差用于动作和物体识别,因此双眼视觉系统是神经科学中理解基本感觉线索如何转化为行为相关信号的有价值的模型系统。在这篇综述中,我们考虑MRI如何有助于理解人类大脑的双眼视觉和深度感知。首先,MRI提供了同时成像整个大脑的能力,以比较特定视觉区域对深度感知的贡献。大量使用功能性核磁共振成像的工作已经导致了对涉及深度感知的大脑区域的广泛网络的理解,以及在单个视觉区域内双目处理的精细尺度宏观组织。其次,MRI可以利用磁共振光谱揭示双目联合的机制信息。该方法可以量化GABA和谷氨酸等神经递质在大脑受限区域的作用,并评估这些抑制性和兴奋性神经化学物质在双眼视觉中的作用。第三,利用弥散磁共振成像可以测量深度感知背后的通路的性质和微观结构。理解这些通路可以让我们深入了解与深度感知有关的区域之间联系的重要性。最后,MRI可以帮助了解由弱视引起的视觉系统变化,弱视是一种儿童时期双眼视力发育不正常的神经疾病。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Investigating the human binocular visual system using multi-modal magnetic resonance imaging.

Having two forward-facing eyes with slightly different viewpoints enables animals, including humans, to discriminate fine differences in depth (disparities), which can facilitate interaction with the world. The binocular visual system starts in the primary visual cortex because that is where information from the eyes is integrated for the first time. Magnetic resonance imaging (MRI) is an ideal tool to non-invasively investigate this system since it can provide a range of detailed measures about structure, function, neurochemistry and connectivity of the human brain. Since binocular disparity is used for both action and object recognition, the binocular visual system is a valuable model system in neuroscience for understanding how basic sensory cues are transformed into behaviourally relevant signals. In this review, we consider how MRI has contributed to the understanding of binocular vision and depth perception in the human brain. Firstly, MRI provides the ability to image the entire brain simultaneously to compare the contribution of specific visual areas to depth perception. A large body of work using functional MRI has led to an understanding of the extensive networks of brain areas involved in depth perception, but also the fine-scale macro-organisation for binocular processing within individual visual areas. Secondly, MRI can uncover mechanistic information underlying binocular combination with the use of MR spectroscopy. This method can quantify neurotransmitters including GABA and glutamate within restricted regions of the brain, and evaluate the role of these inhibitory and excitatory neurochemicals in binocular vision. Thirdly, it is possible to measure the nature and microstructure of pathways underlying depth perception using diffusion MRI. Understanding these pathways provides insight into the importance of the connections between areas implicated in depth perception. Finally, MRI can help to understand changes in the visual system resulting from amblyopia, a neural condition where binocular vision does not develop correctly in childhood.

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来源期刊
Perception
Perception 医学-心理学
CiteScore
2.80
自引率
5.90%
发文量
74
审稿时长
4-8 weeks
期刊介绍: Perception is a traditional print journal covering all areas of the perceptual sciences, but with a strong historical emphasis on perceptual illusions. Perception is a subscription journal, free for authors to publish their research as a Standard Article, Short Report or Short & Sweet. The journal also publishes Editorials and Book Reviews.
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