Quantitative phase imaging of retinal cells (1701.08854v1)

Abstract: The health of cells found in the inner retinal layers of the human eye is crucial to understand the onset of diseases of the retina such as macular degeneration and retinopathy. A challenge is to periodically image these cells in human eyes to detect abnormalities well before physiological and pathological changes occur. However, in vivo imaging of many of these cells is still elusive despite the phenomenal advances in Optical Coherence Tomography (OCT) and Adaptive Optics systems. It stems from the fact that cell contrast in reflection is extremely low. Here, we report a major advance towards this goal by proposing and demonstrating a method to visualize these cells with high contrast and resolution. The method uses a transcleral illumination which provides a high numerical aperture in a dark field configuration. The light backscattered by the Retinal Pigment Epithelium (RPE) and Choroid layer provides a forward illumination for the upper layer of the retina, thus providing a transmission illumination condition. By collecting the scattered light through the pupil, the partially coherent illumination produces dark field images, which are combined to reconstruct a quantitative phase image with twice the numerical aperture given by the eye's pupil. The retrieved quantitative phase images (QPI) of cells in ex vivo human and pig's eyes are validated with those taken with a standard QPI system. We then report, to our knowledge, the very first human in vivo phase images of inner retinal cells with high contrast.