Adaptive spectroscopic visible-light optical coherence tomography for human retinal oximetry

Abstract

Alterations in the retinal oxygen saturation (sO₂) and oxygen consumption are associated with nearly all blinding diseases. A technology that can accurately measure retinal sO₂ has the potential to improve ophthalmology care significantly. Recently, visible-light optical coherence tomography (vis-OCT) showed great promise for noninvasive, depth-resolved measurement of retinal sO₂ as well as ultra-high resolution anatomical imaging. We discovered that spectral contaminants (SC), if not correctly removed, could lead to incorrect vis-OCT sO₂ measurements. There are two main types of SCs associated with vis-OCT systems and eye conditions, respectively. Their negative influence on sO₂ accuracy is amplified in human eyes due to stringent laser power requirements, eye motions, and varying eye anatomies. We developed an adaptive spectroscopic vis-OCT (Ads-vis-OCT) method to iteratively remove both types of SCs. We validated Ads-vis-OCT in ex vivo bovine blood samples against a blood-gas analyzer. We further validated Ads-vis-OCT in 125 unique retinal vessels from 18 healthy subjects against pulse-oximeter readings, setting the stage for clinical adoption of vis-OCT.