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Proceedings Paper

Monte Carlo modeling of tissue autofluorescence measurement and imaging
Author(s): Haishan Zeng; Calum E. MacAulay; Branko Palcic; David I. McLean
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Paper Abstract

The major objective of this theoretical modeling was to examine the quantitative relationships between the microscopic properties of tissue and the macroscopic in vivo autofluorescence measurements. The modeling was carried out using skin tissue as an example. Monte Carlo simulation was used to model the excitation laser light distribution in and the autofluorescence escape process from skin tissue. The processes of fluorescence escape was modeled as the escape process from an isotropic point source embedded inside the tissue. The fractional contributions of different skin layers to the measured total in vivo autofluorescence signal were calculated and demonstrate good agreements with the results estimated from our laser induced autofluorescence decay experiments. This modeling also yielded the spatial resolution resolvable using tissue autofluorescence imaging. It was found to be worse than diffraction effect limited spatial resolution (equals the wavelength of light) and became significantly degraded for fluorescence sources deep inside the tissue.

Paper Details

Date Published: 19 May 1994
PDF: 11 pages
Proc. SPIE 2135, Advances in Laser and Light Spectroscopy to Diagnose Cancer and Other Diseases, (19 May 1994); doi: 10.1117/12.175985
Show Author Affiliations
Haishan Zeng, British Columbia Cancer Agency (Canada)
Calum E. MacAulay, British Columbia Cancer Agency (Canada)
Branko Palcic, British Columbia Cancer Agency (Canada)
David I. McLean, British Columbia Cancer Agency (Canada)


Published in SPIE Proceedings Vol. 2135:
Advances in Laser and Light Spectroscopy to Diagnose Cancer and Other Diseases
Robert R. Alfano, Editor(s)

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