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The Biomechanical Response of the Cornea in Orthokeratology

Jinfang Wu, Wenxuan Fang, Huiwen Xu, Xiaode Liu, Dongliang Zhao, Qiguo Rong

2021Frontiers in Bioengineering and Biotechnology30 citationsDOIOpen Access PDF

Abstract

the finite element method, numerical models with different corneal curvatures, corneal thicknesses, and myopia reduction degrees had been developed and validated to simulate the corneal response and quantify the changes in maximum stress in the central and peripheral corneal areas during orthokeratology. The influence of the factors on corneal response had been analyzed by using median quantile regression. A partial eta squared value in analysis of variance models was established to compare the effect size of these factors. The results showed central and peripheral corneal stress responses changed significantly with increased myopia reduction, corneal curvature, and corneal thickness. The target myopia reduction had the greatest effect on the central corneal stress value (partial eta square = 0.9382), followed by corneal curvature (partial eta square = 0.5650) and corneal thickness (partial eta square = 0.1975). The corneal curvature had the greatest effect on the peripheral corneal stress value (partial eta square = 0.5220), followed by myopia reduction (partial eta square = 0.2375) and corneal thickness (partial eta square = 0.1972). In summary, the biomechanical response of the cornea varies significantly with the change in corneal conditions and lens designs. Therefore, the orthokeratology lens design and the lens fitting process should be taken into consideration in clinical practice, especially for patients with high myopia and steep corneas.

Topics & Concepts

OrthokeratologyCorneaOphthalmologyCorneal topographyLens (geology)MedicineOpticsPhysicsCorneal surgery and disordersOphthalmology and Visual Impairment StudiesOcular Surface and Contact Lens