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Non-invasive in vivo imaging of human corneal microstructures with optical coherence microscopy

Hadiya Farhath Pattan, Xiao Liu, Patrice Tankam

2023Biomedical Optics Express13 citationsDOIOpen Access PDF

Abstract

Non-invasive imaging systems with cellular-level resolution offer the opportunity to identify biomarkers of the early stage of corneal diseases, enabling early intervention, monitoring of disease progression, and evaluating treatment efficacy. In this study, a non-contact polarization-dependent optical coherence microscope (POCM) was developed to enable non-invasive in vivo imaging of human corneal microstructures. The system integrated quarter-wave plates into the sample and reference arms of the interferometer to enable deeper penetration of light in tissues as well as mitigate the strong specular reflection from the corneal surface. A common-path approach was adopted to enable control over the polarization in a free space configuration, thus alleviating the need for a broadband polarization-maintained fiber. The POCM achieved volumetric imaging of corneal microstructures, including endothelial cells over a field of view 0.5 × 0.5 mm 2 with an almost isotropic resolution of ∼2.2 µm and a volume (500 × 500 × 2048 voxels) rate of 1 Hz. A self-interference approach between the corneal surface and underlying layers was also developed to lessen the corneal curvature and axial motion artifacts, thus enabling high-resolution imaging of microstructures in the anterior cornea, including squamous epithelial cells, wing epithelial cells, basal epithelial cells, sub-basal nerve plexus, and stromal keratocytes.

Topics & Concepts

Optical coherence tomographyOpticsMicroscopyPreclinical imagingOptical imagingCoherence (philosophical gambling strategy)Confocal microscopyPoint spread functionIn vivoMaterials sciencePhysicsBiologyBiotechnologyQuantum mechanicsOptical Coherence Tomography ApplicationsCorneal surgery and disordersGlaucoma and retinal disorders