Monte Carlo analysis of single fiber reflectance spectroscopy: photon path length and sampling depth

Monte Carlo analysis of single fiber reflectance spectroscopy: photon path length and sampling depth

Single fiber reflectance spectroscopy is a method to noninvasively quantitate tissue absorption and scattering properties. This study utilizes a Monte Carlo (MC) model to investigate the effect that optical properties have on the propagation of photons that are collected during the single fiber refl...

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Bibliographic Details
Published in:Physics in medicine & biology Vol. 54; no. 22; p. 6991
Main Authors: Kanick, S C, Robinson, D J, Sterenborg, H J C M, Amelink, A
Format: Journal Article
Language:English
Published: England 21-11-2009
Subjects:
Computer-Aided Design
Equipment Design
Equipment Failure Analysis
Fiber Optic Technology - instrumentation
Light
Monte Carlo Method
Photons
Reproducibility of Results
Scattering, Radiation
Sensitivity and Specificity
Spectrum Analysis - instrumentation
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Summary:Single fiber reflectance spectroscopy is a method to noninvasively quantitate tissue absorption and scattering properties. This study utilizes a Monte Carlo (MC) model to investigate the effect that optical properties have on the propagation of photons that are collected during the single fiber reflectance measurement. MC model estimates of the single fiber photon path length (L(SF)) show excellent agreement with experimental measurements and predictions of a mathematical model over a wide range of optical properties and fiber diameters. Simulation results show that L(SF) is unaffected by changes in anisotropy (g epsilon [0.8, 0.9, 0.95]), but is sensitive to changes in phase function (Henyey-Greenstein versus modified Henyey-Greenstein). A 20% decrease in L(SF) was observed for the modified Henyey-Greenstein compared with the Henyey-Greenstein phase function; an effect that is independent of optical properties and fiber diameter and is approximated with a simple linear offset. The MC model also returns depth-resolved absorption profiles that are used to estimate the mean sampling depth (Z(SF)) of the single fiber reflectance measurement. Simulated data are used to define a novel mathematical expression for Z(SF) that is expressed in terms of optical properties, fiber diameter and L(SF). The model of sampling depth indicates that the single fiber reflectance measurement is dominated by shallow scattering events, even for large fibers; a result that suggests that the utility of single fiber reflectance measurements of tissue in vivo will be in the quantification of the optical properties of superficial tissues.
ISSN:1361-6560
DOI:10.1088/0031-9155/54/22/016