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In this thesis we present the application of polarized light to characterize porcine liver
and phantoms with matched bulk optical properties, correlate the depolarization of
tissues with transport albedo and evaluate the severity of liver injury. We have used
the Mueller matrix analysis and polar decomposition method for extraction of
individual polarization properties in this thesis.
We investigated the polarization properties of thick samples (1 cm) of porcine liver,
intralipid phantoms and polystyrene micro-spheres phantoms with matched bulk
optical properties. Significant depolarization differences between porcine liver and
phantoms are observed. Contrary to previously reported results for transmission
geometry, our results show the enhanced polarization preservation for porcine liver
tissues as compared to fabricated phantoms, particularly in the backscattering
detection geometry. Moreover, the intralipid phantoms, polarization behavior is well-
approximated with liver tissue as compared to the polystyrene sphere phantoms.
Polarized light imaging was employed to investigate the correlation between light
depolarization and transport albedo for six different isotropic and anisotropic thick
tissues in both transmission and backscattering mode. Total, linear and circular
depolarization rates were observed to be dependent on the measured transport
albedos, where depolarization increases with transport albedo for all type of tissues
independent of detection geometries. Higher depolarization rates were observed for
anisotropic tissues as compared to isotropic ones for comparable transport albedos,
demonstrating the birefringence-caused depolarization in addition to scattering-caused
depolarization.
The ex vivo severity assessment of different liver injuries induced by carbon tetra
chloride (CCl4) was probed by polarized light in the visible spectral range. Less
injured liver samples show higher linear retardance as compared to normal liver
tissue, while worse injuries correspond to almost no retardance. Fibrosis is the likely
cause at less severe injuries results in higher observed linear retardance whereas more
serious injuries destroy any kind of organization and hence yield no retardance.
Furthermore, total- linear- and circular-depolarizations were observed to decrease
with increased injuries. Most likely causes include change of transport albedo and
relative refractive index of extracellular matrix. |
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