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心理物理学反向相关研究揭示弱视患者的朝向调谐更广泛,反应时间更长。

Psychophysical Reverse Correlation Revealed Broader Orientation Tuning and Prolonged Reaction Time in Amblyopia.

机构信息

School of Ophthalmology & Optometry and Eye Hospital, Wenzhou Medical University, Wenzhou, Zhejiang, China.

Key Laboratory of Behavioral Science, Institute of Psychology, Chinese Academy of Sciences, Chaoyang District, Beijing, China.

出版信息

Invest Ophthalmol Vis Sci. 2022 May 2;63(5):3. doi: 10.1167/iovs.63.5.3.

DOI:10.1167/iovs.63.5.3
PMID:35503229
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9078079/
Abstract

PURPOSE

Neural selectivity of orientation is a fundamental property of visual system. We aim to investigate whether and how the orientation selectivity changes in amblyopia.

METHODS

Seventeen patients with amblyopia (27.1 ± 7.1 years) and 18 healthy participants (25.1 ± 2.7 years) took part in this study. They were asked to continuously detect vertical gratings embedded in a stream of randomly oriented gratings. Using a technique of subspace reverse correlation, the orientation-time perceptive field (PF) for the atypical grating detection task was derived for each participant. Detailed comparisons were made between the PFs measured with the amblyopic and healthy eyes.

RESULTS

The PF of the amblyopic eyes showed significant differences in orientation and time domain compared with that of the normal eyes (cluster-based permutation test, ps < 0.05), with broader bandwidth of orientation tuning (31.41 ± 10.59 degrees [mean ± SD] vs. 24.76 ± 6.85 degrees, P = 0.039) and delayed temporal dynamics (483 ± 68 ms vs. 425 ± 58 ms, P = 0.015). None of the altered PF properties correlated with the contrast sensitivity at 1 cycle per degree (c/deg) in amblyopia. No difference in PFs between the dominant and non-dominant eyes in the healthy group was found.

CONCLUSIONS

The altered orientation-time PF to the low spatial frequency and high contrast stimuli suggests amblyopes had coarser orientation selectivity and prolonged reaction time. The broader orientation tuning probably reflects the abnormal lateral interaction in the primary visual cortex, whereas the temporal delay might indicate a high level deficit.

摘要

目的

朝向的神经选择性是视觉系统的基本属性。我们旨在研究弱视中这种朝向选择性是否以及如何发生变化。

方法

17 名弱视患者(27.1±7.1 岁)和 18 名健康受试者(25.1±2.7 岁)参与了本研究。他们被要求连续检测嵌入在随机取向光栅流中的垂直光栅。使用子空间反向相关技术,为每个参与者推导出用于非典型光栅检测任务的朝向-时间感知域(PF)。对用弱视眼和正常眼测量的 PF 进行了详细比较。

结果

与正常眼相比,弱视眼的 PF 在朝向和时域上均显示出显著差异(基于聚类的置换检验,p<0.05),具有更宽的朝向调谐带宽(31.41±10.59 度[均值±标准差]与 24.76±6.85 度,P=0.039)和延迟的时间动态(483±68 ms 与 425±58 ms,P=0.015)。弱视中 1 周期每度(c/deg)对比度敏感度的改变与任何 PF 特性均无关。在健康组中,主导眼和非主导眼的 PF 之间没有差异。

结论

对低空间频率和高对比度刺激的改变的朝向-时间 PF 提示弱视者具有更粗糙的朝向选择性和延长的反应时间。更宽的朝向调谐可能反映了初级视觉皮层中的异常侧向相互作用,而时间延迟可能表明存在高级别缺陷。

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