鸡眼在没有视觉线索的情况下也能从晶状体补偿中恢复过来。

Chick Eyes Can Recover from Lens Compensation without Visual Cues.

机构信息

College of Optometry, State University of New York, New York, New York.

School of Psychology, Faculty of Science, University of Newcastle, Callaghan, New South Wales, Australia.

出版信息

Optom Vis Sci. 2020 Aug;97(8):606-615. doi: 10.1097/OPX.0000000000001542.

DOI:10.1097/OPX.0000000000001542

PMID:32740557

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7483859/

Abstract

SIGNIFICANCE

This study shows that nonvisual mechanism(s) can guide chick eyes to recover from myopia or hyperopia bidirectionally to regain their age-matched length. Because eye growth control is phylogenetically conserved across many species, it is possible that, in general, emmetropization mechanisms are not exclusively based on a local visual feedback system.

PURPOSE

Across species, growing eyes compensate for imposed defocus by modifying their growth, showing the visual controls on eye growth and emmetropization. When the spectacle lens is removed, the eyes rapidly recover back to a normal size similar to that in the untreated eyes. We asked whether this recovery process was dependent on visual feedback or whether it might be guided by intrinsic nonvisual mechanisms.

METHODS

Chicks wore either a +7 (n = 16) or -7 D (n = 16) lens over one eye for 4 to 7 days; the fellow eye was left untreated. After lens removal, half were recovered in darkness and half in white light. Refractive error and ocular dimensions were measured before and after lens treatment and after recovery with a Hartinger refractometer and A-scan biometer, respectively.

RESULTS

Whereas chick eyes completely recovered from prior lens treatment under normal light after 2 days, they also partially recovered from prior hyperopia (by 60%) and myopia (by 69%) after being kept in darkness for 3 days: a +7 and -7 D lens induced a difference between the eyes of +7.08 and -4.69 D, respectively. After recovery in darkness, the eyes recovered by 3.18 and 2.88 D, respectively.

CONCLUSIONS

In the absence of visual cues, anisometropic eyes can modify and reverse their growth to regain a similar length to their fellow untreated eye. Because eye growth control is phylogenetically conserved across many species, it is possible that nonvisual mechanisms may contribute more generally to emmetropization and that recovery from anisometropic refractive errors may not be wholly visually controlled.

摘要

意义

本研究表明，非视觉机制可以引导小鸡眼睛双向恢复远视或近视，使其恢复到与年龄匹配的长度。由于眼生长控制在许多物种中是系统发生保守的，因此，一般来说，正视化机制可能不仅仅基于局部视觉反馈系统。

目的

在不同物种中，正在生长的眼睛通过改变其生长来补偿施加的离焦，从而显示出对眼生长和正视化的视觉控制。当去除眼镜后，眼睛会迅速恢复到类似于未经处理的眼睛的正常大小。我们想知道这个恢复过程是否依赖于视觉反馈，或者它是否可能由内在的非视觉机制引导。

方法

小鸡的一只眼睛戴上+7（n=16）或-7 D（n=16）的镜片 4 到 7 天；另一只眼睛不做处理。去除镜片后，一半在黑暗中恢复，一半在白光下恢复。在用 Hartinger 折射仪和 A 扫描生物测量仪分别测量之前和之后的镜片治疗以及恢复后的屈光不正和眼尺寸。

结果

尽管小鸡眼睛在正常光照下 2 天后完全从先前的镜片治疗中恢复，但在黑暗中 3 天后，它们也部分地从先前的远视（60%）和近视（69%）中恢复：+7 和-7 D 的镜片分别在眼睛之间产生了+7.08 和-4.69 D 的差异。在黑暗中恢复后，眼睛分别恢复了 3.18 和 2.88 D。

结论

在没有视觉线索的情况下，屈光参差的眼睛可以改变并逆转其生长，以恢复到与其未治疗的同伴眼睛相似的长度。由于眼生长控制在许多物种中是系统发生保守的，因此非视觉机制可能更普遍地有助于正视化，并且从屈光不正的恢复可能不完全由视觉控制。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/ca97/7483859/5a46ae6d0519/nihms-1607848-f0001.jpg

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鸡眼在没有视觉线索的情况下也能从晶状体补偿中恢复过来。

Chick Eyes Can Recover from Lens Compensation without Visual Cues.

机构信息

出版信息

SIGNIFICANCE

PURPOSE

METHODS

RESULTS

CONCLUSIONS

意义

目的

方法

结果

结论

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