Abstract
Polarization sensitive optical coherence tomography (PS-OCT) is a functional extension of OCT. In addition to imaging based on tissue reflectivity, PS-OCT also enables depth-resolved mapping of sample polarization properties such as phase-retardation, birefringent axis orientation, Stokes vectors, and degree of polarization uniformity (DOPU). In this study, PS-OCT was used to investigate the polarization properties of melanin. In-vitro measurements in samples with varying melanin concentrations revealed polarization scrambling, i.e. depolarization of backscattered light. Polarization scrambling in the PS-OCT images was more pronounced for higher melanin concentrations and correlated with the concentration of the melanin granules in the phantoms. Moreover, in-vivo PS-OCT was performed in the retinas of normal subjects and individuals with albinism. Unlike in the normal eye, polarization scrambling in the retinal pigment epithelium (RPE) was less pronounced or even not observable in PS-OCT images of albinos. These results indicate that the depolarizing appearance of pigmented structures like, for instance, the RPE is likely to be caused by the melanin granules contained in these cells.
Highlights
Ever since its first presentation in 1991, optical coherence tomography (OCT) has found applications in manifold fields [1]
The degree of polarization uniformity (DOPU) images are color coded from blue (DOPU = 0) to red (DOPU = 1)
Pixels with intensities below a threshold set to ~3.5 standard deviations of the noise intensity above the mean noise level are displayed in grey
Summary
Ever since its first presentation in 1991, optical coherence tomography (OCT) has found applications in manifold fields [1]. Its ability to perform non-invasive, non-contact imaging of weakly scattering structures with micrometer-scale resolution in real time has made OCT attractive for investigating biological tissues in vivo [2,3,4]. OCT has been applied for volumetric high-resolution imaging in biomedical fields such as endoscopic investigations of the gastrointestinal tract or intravascular probing. The most prominent application of OCT, is in ophthalmology where it has become an essential tool in everyday clinical routine. OCT’s ability to resolve single retinal layers has been used for diagnosis of pathology, monitoring disease progression and follow-up imaging of response to therapy [9]
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