Induced Myopia Associated with Increased Scleral Creep in Chick and Tree Shrew Eyes

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Induced Myopia Associated with Increased Scleral Creep in Chick and Tree Shrew Eyes

John R. Phillips¹, Mohammad Khalaj² and Neville A. McBrien³

¹ From the Department of Optometry and Vision Science, University of Auckland, New Zealand; ² Medical Science School of Ghazvin, Iran; ³ Department of Optometry and Vision Sciences, University of Melbourne, Parkville, Victoria, Australia.

PURPOSE. To investigate the role of scleral creep in the axialelongation of chick and tree shrew eyes with induced myopia.

METHODS. Form-deprivation myopia was induced with a diffusingoccluder worn over one eye. Scleral samples from the posteriorpole and equatorial regions of myopic, contralateral (control),and age-matched normal chick and tree shrew eyes were loadedin vitro with a force of 5 g for 20 minutes while creep extensionwas monitored. The elastic behavior of sclera from myopic, control,and normal chick eyes was also compared.

RESULTS. In both chick and tree shrew, posterior and equatorialscleral samples from myopic eyes had significantly (P < 0.05)greater creep extensions than equivalent samples from controland normal eyes (n = 10, each group). Among individual treeshrews the difference in creep rate between the sample fromthe myopic eye and that from the control eye correlated withvitreous chamber elongation (r = 0.746, P < 0.05) and developmentof myopia (r = 0.792, P < 0.01) in the deprived eye. No suchassociation was found in the data from chicks. The elastic propertiesof chick sclera were unaffected in form-deprivation myopia.

CONCLUSIONS. In chick and tree shrew, form-deprivation myopiais associated with increased creep rate of posterior and equatorialsclera. In tree shrew, the correlation between increased scleralcreep rate and vitreous chamber elongation in myopic eyes supportsthe hypothesis that induced changes in the axial length of themammalian eye are mediated by changes in the creep propertiesof the sclera.

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