16 February 2007 Phase-dispersion light scattering for quantitative size-imaging of spherical scatterers
Author Affiliations +
Abstract
Using phase-dispersion spectra measured with optical coherence tomography (OCT) in the frequency domain, we demonstrated the quantitative sizing of multiple spherical scatterers on a surface. We modeled the light scattering as a slab-mode resonance and determined the size of the scatterers from a Fourier transform of the measured phasedispersion spectra. Using a swept-source OCT system, we mapped the detected size of the scatters to the intensity of a two-dimensional surface image. The image was formed by raster-scanning a collimated beam of 200 μm diameter across a sample with distinct size domains. The image shows a clear distinction between deposited polystyrene microspheres of 26 and 15 μm average sizes. In a separate experiment, we demonstrated tissue-relevant sizing of scatters as small as 5 μm with a Fourier domain OCT system that utilized 280 nm of bandwidth from a super-continuum source. Our previous studies have demonstrated that the light scattered from a single sphere is, in general, nonminimum- phase; therefore, phase spectra can provide unique information about scattered light not available from intensity spectra alone. Also, measurements of phase spectra do not require background normalization to correct for the spectral shape of light sources or the spectral absorption of specimens. The results we report here continue our efforts towards combining intensity and phase spectra to enable improved quantitative analysis of complex tissue structures.
© (2007) COPYRIGHT Society of Photo-Optical Instrumentation Engineers (SPIE). Downloading of the abstract is permitted for personal use only.
Tasshi Dennis, Shellee D. Dyer, Andrew Dienstfrey, "Phase-dispersion light scattering for quantitative size-imaging of spherical scatterers", Proc. SPIE 6446, Biomedical Applications of Light Scattering, 644609 (16 February 2007); doi: 10.1117/12.699244; https://doi.org/10.1117/12.699244
PROCEEDINGS
8 PAGES


SHARE
Back to Top