{"title":"前注视会增强和重塑对比敏感度功能,但视场周围的情况各不相同。","authors":"Yuna Kwak, Yukai Zhao, Zhong-Lin Lu, Nina Maria Hanning, Marisa Carrasco","doi":"10.1523/ENEURO.0243-24.2024","DOIUrl":null,"url":null,"abstract":"<p><p>Contrast sensitivity (CS), which constrains human vision, decreases from fovea to periphery, from the horizontal to the vertical meridian, and from the lower vertical to the upper vertical meridian. It also depends on spatial frequency (SF), and the contrast sensitivity function (CSF) depicts this relation. To compensate for these visual constraints, we constantly make saccades and foveate on relevant objects in the scene. Already before saccade onset, presaccadic attention shifts to the saccade target and enhances perception. However, it is unknown whether and how it modulates the interplay between CS and SF, and if this effect varies around polar angle meridians. CS enhancement may result from a horizontal or vertical shift of the CSF, increase in bandwidth, or any combination. In addition, presaccadic attention could enhance CS similarly around the visual field, or it could benefit perception more at locations with poorer performance (i.e., vertical meridian). Here, we investigated these possibilities by extracting key attributes of the CSF of human observers. The results reveal that presaccadic attention (1) increases CS across SF, (2) increases the most preferred and the highest discernable SF, and (3) narrows the bandwidth. Therefore, presaccadic attention helps bridge the gap between presaccadic and postsaccadic input by increasing visibility at the saccade target. Counterintuitively, this CS enhancement was more pronounced where perception is better-along the horizontal than the vertical meridian-exacerbating polar angle asymmetries. Our results call for an investigation of the differential neural modulations underlying presaccadic perceptual changes for different saccade directions.</p>","PeriodicalId":11617,"journal":{"name":"eNeuro","volume":" ","pages":""},"PeriodicalIF":2.7000,"publicationDate":"2024-09-12","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC11397507/pdf/","citationCount":"0","resultStr":"{\"title\":\"Presaccadic Attention Enhances and Reshapes the Contrast Sensitivity Function Differentially around the Visual Field.\",\"authors\":\"Yuna Kwak, Yukai Zhao, Zhong-Lin Lu, Nina Maria Hanning, Marisa Carrasco\",\"doi\":\"10.1523/ENEURO.0243-24.2024\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>Contrast sensitivity (CS), which constrains human vision, decreases from fovea to periphery, from the horizontal to the vertical meridian, and from the lower vertical to the upper vertical meridian. It also depends on spatial frequency (SF), and the contrast sensitivity function (CSF) depicts this relation. To compensate for these visual constraints, we constantly make saccades and foveate on relevant objects in the scene. Already before saccade onset, presaccadic attention shifts to the saccade target and enhances perception. However, it is unknown whether and how it modulates the interplay between CS and SF, and if this effect varies around polar angle meridians. CS enhancement may result from a horizontal or vertical shift of the CSF, increase in bandwidth, or any combination. In addition, presaccadic attention could enhance CS similarly around the visual field, or it could benefit perception more at locations with poorer performance (i.e., vertical meridian). Here, we investigated these possibilities by extracting key attributes of the CSF of human observers. The results reveal that presaccadic attention (1) increases CS across SF, (2) increases the most preferred and the highest discernable SF, and (3) narrows the bandwidth. Therefore, presaccadic attention helps bridge the gap between presaccadic and postsaccadic input by increasing visibility at the saccade target. Counterintuitively, this CS enhancement was more pronounced where perception is better-along the horizontal than the vertical meridian-exacerbating polar angle asymmetries. 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引用次数: 0
摘要
对比敏感度制约着人类的视觉,从眼窝到周边,从水平经线到垂直经线,以及从垂直下经线到垂直上经线,对比敏感度都在下降。对比敏感度函数(CSF)描述了对比敏感度如何取决于空间频率(SF)。为了弥补这些视觉上的限制,我们会不断地进行眼球移动,以聚焦于场景中的相关物体。在囊回开始之前,前囊回注意力就已经转移到囊回目标上,从而增强了感知。然而,人们还不知道它是否以及如何调节对比敏感度和 SF 之间的相互作用,也不知道这种效应是否会随着极角位置的变化而变化。对比敏感度的增强可能是 CSF 水平或垂直移动、带宽增加或任何组合的结果。此外,累积前注意也可能在视野周围同样增强对比敏感度,或者在表现较差的位置(即垂直子午线)更有利于感知。在这里,我们通过提取人类观察者 CSF 的关键属性来研究这些可能性。研究结果表明,前积聚注意(1)增加了各SF的对比敏感度;(2)增加了最偏好和可辨别度最高的SF;(3)缩小了带宽。因此,前摄动注意通过增加囊状目标的能见度,有助于弥合前摄动和后摄动输入之间的差距。与直觉相反的是,在水平经线比垂直经线感知更好的地方,对比敏感度的前摄动增强更为明显,从而加剧了极角不对称。我们的研究结果要求对不同囊回方向的囊回前知觉变化背后的不同神经调制进行研究。 意义说明 对比敏感度函数(CSF)描述了我们感知对比的能力如何取决于空间频率。对比敏感度在眼窝处最高,而在外围则会降低,尤其是在沿垂直子午线的位置。因此,我们会通过眼球移动来观察物体的细节。在我们移动眼睛之前,预视注意就已经增强了对目标位置的感知。但是,它如何影响对比敏感度和空间频率之间的相互作用?通过使用层次贝叶斯建模,我们发现前注视会增强和重塑 CSF,使外围为即将到来的固定做好准备。有趣的是,在视力较强的水平位置,前积聚注意的作用更大,这表明水平方向的眼球运动比垂直方向的眼球运动更平滑。
Presaccadic Attention Enhances and Reshapes the Contrast Sensitivity Function Differentially around the Visual Field.
Contrast sensitivity (CS), which constrains human vision, decreases from fovea to periphery, from the horizontal to the vertical meridian, and from the lower vertical to the upper vertical meridian. It also depends on spatial frequency (SF), and the contrast sensitivity function (CSF) depicts this relation. To compensate for these visual constraints, we constantly make saccades and foveate on relevant objects in the scene. Already before saccade onset, presaccadic attention shifts to the saccade target and enhances perception. However, it is unknown whether and how it modulates the interplay between CS and SF, and if this effect varies around polar angle meridians. CS enhancement may result from a horizontal or vertical shift of the CSF, increase in bandwidth, or any combination. In addition, presaccadic attention could enhance CS similarly around the visual field, or it could benefit perception more at locations with poorer performance (i.e., vertical meridian). Here, we investigated these possibilities by extracting key attributes of the CSF of human observers. The results reveal that presaccadic attention (1) increases CS across SF, (2) increases the most preferred and the highest discernable SF, and (3) narrows the bandwidth. Therefore, presaccadic attention helps bridge the gap between presaccadic and postsaccadic input by increasing visibility at the saccade target. Counterintuitively, this CS enhancement was more pronounced where perception is better-along the horizontal than the vertical meridian-exacerbating polar angle asymmetries. Our results call for an investigation of the differential neural modulations underlying presaccadic perceptual changes for different saccade directions.
期刊介绍:
An open-access journal from the Society for Neuroscience, eNeuro publishes high-quality, broad-based, peer-reviewed research focused solely on the field of neuroscience. eNeuro embodies an emerging scientific vision that offers a new experience for authors and readers, all in support of the Society’s mission to advance understanding of the brain and nervous system.