Quantifying the effects of hydration on corneal stiffness with noncontact optical coherence elastography

Abstract

To quantify the effects of the hydration state on the Young's modulus of the cornea. Biomedical Optics Laboratory, University of Houston, Houston, Texas, USA. Experimental study. Noncontact, dynamic optical coherence elastography (OCE) measurements were taken of insitu rabbit corneas in the whole eye-globe configuration (n=10) and at an artificially controlled intraocular pressure of 15mm Hg. Baseline OCE measurements were taken by topically hydrating the corneas with saline for 1hour. The corneas were then dehydrated topically with a 20% dextran solution for another hour, and the OCE measurements were repeated. A finite element method was used to quantify the Young's modulus of the corneas based on the OCE measurements. The thickness of the corneas shrank considerably after topical addition of the 20% dextran solution (∼680 μm to ∼370 μm), and the OCE-measured elastic-wave speed correspondingly decreased (∼3.2m/s to ∼2.6m/s). The finite element method results showed an increase in Young's modulus (500kPa to 800kPa) resulting from dehydration and subsequent thinning. Young's modulus increased significantly as the corneas dehydrated and thinned, showing that corneal geometry and hydration state are critical factors for accurately quantifying corneal biomechanical properties.