In vivo human corneal natural frequency quantification using dynamic optical coherence elastography: Repeatability and reproducibility.

Abstract

Reliable and quantitative assessment of corneal biomechanics is important for the detection and treatment of corneal disease. The present study evaluates the repeatability and reproducibility of a novel optical coherence tomography (OCT)-based elastography (OCE) method for in vivo quantification of corneal natural frequency in 20 normal human eyes. Sub-micron corneal oscillations were induced by repeated low-force (13\u202fPa) microliter air pulses at the corneal apex and were observed by common-path phase-sensitive OCT imaging adjacent to a measurement region of 1-6.25\u202fmm2. Corneal natural frequencies were quantified using a single degree of freedom model based on the corneal oscillations. Corneal natural frequencies ranged from 234 to 277\u202fHz (coefficient of variation: 3.2%; n\u202f=\u202f286 for a 2.5\u202f×\u202f2.5\u202fmm2 area; time: 28.6\u202fs). The same natural frequencies can be acquired using a smaller sampling size (n\u202f=\u202f9 for 1\u202fmm2) and a shorter time (0.9\u202fs). Spatial distribution and local changes in natural frequencies can be distinguished using denser sampling (e.g., 26\u202f×\u202f41 points for 2.5\u202f×\u202f5\u202fmm2). This novel optical method demonstrates highly repeatable and reliable in vivo measurements of human corneal natural frequencies. While further studies are required to fully characterize anatomical and structural dependencies, this method may be complementary to the current OCE methods used to estimate Young s modulus from strain- or shear-wave-based measurements for the quantitative determination of corneal biomechanics.