Abstract

To examine the regional changes in human choroidal thickness following short-term exposure to hemifield myopic defocus using optical coherence tomography (OCT). The central 26˚ visual field of the left eye of 25 healthy young adults (mean age 26±5years) was exposed to 60min of clear vision (control session), +3 D full-field, +3 D superior retinal and +3 D inferior retinal myopic defocus, with the right eye occluded. Choroidal thickness across the central 5mm (17°) macular region was examined before and after 60min of defocus using a high-resolution, foveal centred vertical OCT line scan, with optical defocus simultaneously imposed using a Badal optometer and cold mirror system mounted on a Spectralis OCT device. Averaged across the central 5mm macular area, choroidal thickness decreased by -4±7μm during the control session (p=0.01), most likely due to the unique stimulus conditions of this study. The mean macular choroidal thickness increased during full-field (+2±8μm), inferior retinal (+3±7μm) and superior retinal myopic defocus (+5±9μm), representing a significant thickening of the choroid compared to the control session (all p<0.05). The defocus induced changes in macular choroidal thickness differed between the superior and inferior hemiretinal regions (F2.26, 54.27 =29.75, p<0.001). When only the superior retina was exposed to myopic defocus, the choroid thickened in the superior region (+7±8μm, p<0.001), but did not change significantly in the inferior region (+3±9μm, p=0.12). When only the inferior retina was exposed to myopic defocus, the choroid thickened inferiorly (+4±8μm, p=0.005), with no significant change observed in the superior region (+1±8μm, p=0.46). These findings provide evidence supporting a local regional choroidal response to myopic defocus in the human eye, with hemifield myopic defocus leading to significant thickening of the choroid localised to the retinal region exposed to defocus. The novel finding of a localised response of the human choroid to hemifield myopic defocus, particularly in the superior hemiretina, may have important implications in optimising the optical design of myopia control interventions.

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