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Reduction of excitation light leakage to improve near‐infrared fluorescence imaging for tissue surface and deep tissue imaging
Author(s) -
Zhu Banghe,
Rasmussen John C.,
Lu Yujie,
SevickMuraca Eva M.
Publication year - 2010
Publication title -
medical physics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.473
H-Index - 180
eISSN - 2473-4209
pISSN - 0094-2405
DOI - 10.1118/1.3497153
Subject(s) - fluorescence , materials science , medical imaging , fluorescence lifetime imaging microscopy , optical imaging , optics , infrared , excitation , biological tissue , leakage (economics) , optoelectronics , biomedical engineering , medicine , physics , radiology , macroeconomics , quantum mechanics , economics
Purpose: Fluorescence‐enhanced optical imaging using near‐infrared (NIR) light developed for in vivo molecular targeting and reporting of various diseases provides promising opportunities for diagnostic imaging. However, the measurement sensitivity of NIR fluorescence (NIRF) optical imaging systems is limited by the leakage of the strong backscattered excitation light through rejection filters. In this article, the authors present a systematic method for improving sensitivity and validating the NIRF optical imager currently used for clinical imaging of human lymphatic function. Methods: The proposed systemic method consists of an appropriate filter combination and a collimation optics adapted to an NIRF optical imager. The spectral contributions were first assessed due to the excitation light backscattered from the tissue and from non‐normal‐incidence of the excitation light on the optical filters used in the authors' NIRF clinical imaging system. Then two tests were conducted to assess the system with and without the components of appropriate filters combination and collimation optics using: (1) a phantom to evaluate excitation light leakage as a function of target depth and (2) deployment in an actual human study. Results: The phantom studies demonstrate as much as two to three orders of magnitude reduction in the transmission ratio, indicating that the excitation light leakage can be reduced upon using the appropriate filter combination and collimation optics while an in vivo investigatory human study confirms improved imaging. Conclusions: The method for reducing the excitation light leakage is presented for validating collected signals for fluorescence imaging.

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