In this project the research team will begin to find out whether shining a red LED light at the eyes can slow down the worsening of short-sightedness in children. This is important, because short-sightedness now starts at a younger age and worsens faster than in the past. Many people are at risk of permanently losing their eyesight in middle-age because of short-sightedness. The researchers plan to use red LED light, which is safe to use. Red-light treatment improves the blood flow at the back of the eye, in a layer called "choroid", which can be measured on eye-scans. The team have done a study with healthy adults, which showed that red-light is safe and gently improves the blood flow at the back of the eye. In adults, this has no effect on myopia, because their eyes are fully grown. In children, red-light may slow down myopia, and in this project, the researchers want to find out which level of red-light is needed to have this effect. The researchers will ask 24 children age 5-12 years to use red-light for three minutes twice a day for three months. Three will be 4 groups of children, and each group will use a different level of brightness. The researchers will measure the eye length and the thickness of the choroid at the start and 1 and 3 months later and compare the change in eye length between the different groups. In practice, children will need to use the treatment for several years. The researchers will use the results of this study to prepare a longer study with more children.
Study Type
INTERVENTIONAL
Allocation
NON_RANDOMIZED
Purpose
BASIC_SCIENCE
Masking
NONE
Enrollment
24
Red LED light
University College London
London, London, United Kingdom
Axial length
The researchers will measure the length of the eyeballs using an optical biometer; these are the most sensitive outcome measure in myopia studies, and the least invasive measurement method.
Time frame: 3 months
Spherical equivalent
The team will measure the refractive error (prescription for spectacles) using an open-view autorefractor, as a secondary measure of myopia progression.
Time frame: 3 months
Subfoveal choroidal thickness
The team will acquire an optical coherence tomography scan. On the scan, the researchers will measure the choroidal thickness, which is frequently used as a proxy measure of the treatment effect of interventions to slow myopia progression. The choroid is a vascular layer underneath the retina at the back of the eye.
Time frame: 3 months
Colour contrast sensitivity
As a safety measure, the researchers will measure colour contrast sensitivity on a computer-screen, showing participants coloured symbols on a grey background. This is the most sensitive test for photoreceptor health, the layer of cells in the retina which change light signals to electrical signals.
Time frame: 3 months
Visual acuity
As a secondary safety outcome, the researchers will measure the participant's visual acuity, using a test where participants read letters of reducing size on a chart.
Time frame: 3 months
Tolerability/usability
The researchers will ask participants open-ended questions about their thoughts and experience with using red-light treatment, and about easier ways for children to use it.
Time frame: 3 months
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