Abstract
The human eye is capable of responding to the presence of blur by changing its axial length, so that the retina moves towards the defocused image plane. We measured how quickly the eye length changed in response to both myopic and hyperopic defocus and how quickly the eye length changed when the defocus was removed. Axial length was measured at baseline and every 10 minutes during 1 hour of exposure to monocular defocus (right eye) with the left eye optimally corrected for two defocus conditions (+3 D and −3 D) and a control condition. Recovery was measured for 20 minutes after blur removal. A rapid increase in axial length was observed after exposure (~2 minutes) to hyperopic defocus (+7 ± 5 μm, p < 0.001) while the reduction in axial length with myopic defocus was slower and only statistically significant after 40 minutes (−8 ± 9 μm, p = 0.017). The eye length also recovered toward baseline levels during clear vision more rapidly following hyperopic than myopic defocus (p < 0.0001). These findings provide evidence that the human eye is able to detect and respond to the presence and sign of blur within minutes.
Highlights
The human eye is capable of responding to the presence of blur by changing its axial length, so that the retina moves towards the defocused image plane
Given that the visual system is known to compensate for optical defocus through a gradual improvement in defocused visual acuity (VA) over time[24,25,26,27,28], we examined the association between the time course of changes in defocused VA and axial length during exposure to myopic defocus
The eye appears capable of discerning the sign of defocus rapidly and making compensatory changes in its axial length, which would have the effect of moving the retina in the direction towards the defocused image plane
Summary
The human eye is capable of responding to the presence of blur by changing its axial length, so that the retina moves towards the defocused image plane. Given that no significant change in anterior eye biometry has been observed during short-term imposed defocus, the changes in axial length with defocus have been primarily attributed to rapid changes in choroidal thickness[17,21,23] Whilst these findings collectively imply that the human eye is able to discern the sign of defocus and make changes in the thickness of the choroid and axial length, details concerning how quickly this occurs, how the eye responds to defocus over time, and the time course of the decay of the eye’s response to defocus following the cessation of blur exposure are not well understood.
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