@inproceedings{duncan10b,
  author = {Donald D. Duncan and David G. Fischer and Mehran Daneshbod and Scott A. Prahl},
  title = {Differential interference contrast microscopy for the quantitative assessment of tissue organization},
  booktitle = {SPIE Proceedings on Three-Dimensional and Multidimensional Microscopy: Image Acquisition and Processing {XVII}},
  year = {2010},
  editor = {Jose-Angel Conchello and Carol J. Cogswell and Tony Wilson and Thomas G. Brown},
  number = {7570-0C},
  abstract = {The propagation of light through complex structures, such as biological tissue, is a poorly understood phenomenon. Typically the tissue is envisioned as an effective medium, and Monte Carlo techniques are used to solve the radiative transport equation. In such an approach the medium is characterized in terms of a limited number of physical scatter and absorption parameters, but is otherwise considered homogeneous. For exploration of propagation phenomena such as spatial coherence, however, a physical model of the tissue medium having a multiscale structure is required.\\[3mm] We present a particularly simple means of establishing such a multiscale tissue characterization based on measurements using a differential interference contrast (DIC) microscope. This characterization is in terms of spatially resolved maps of the (polar and azimuthal) angular ray deviations. With such data, tissues can be characterized in terms of their first and second order scatter properties. We discuss a simple means of calibrating a DIC microscope, the measurement procedure and quantitative interpretation of the ensuing data, and give example characterizations for a number of different tissue types. These characterizations are in terms of the scatter phase function and the spatial power spectral density.},
}