Journal
OPTICS LETTERS
Volume 39, Issue 14, Pages 4156-4159Publisher
OPTICAL SOC AMER
DOI: 10.1364/OL.39.004156
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Funding
- National Institutes of Health [R21 CA161782, R21 EB013421]
- National Science Foundation CAREER AWARD [CBET-1149407]
- Div Of Chem, Bioeng, Env, & Transp Sys
- Directorate For Engineering [1149407] Funding Source: National Science Foundation
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Time domain fluorescence molecular tomography (TD-FMT) provides a unique dataset for enhanced quantification and spatial resolution. The time-gate dataset can be divided into two temporal groups around the maximum counts gate, which are early gates and late gates. It is well established that early gates allow for improved spatial resolution and late gates are essential for fluorophore unmixing and concentration quantification. However, the inverse problem of FMT is ill-posed and typically underdetermined, which makes image reconstruction highly susceptible to data noise. More specifically, photon counts are inherently very low at early gates due to high absorption and scattering of tissue, resulting in a low signal-to-noise ratio and unstable reconstructions. In this work, an L-p regularization-based reconstruction algorithm was developed and tested with our wide-field mesh-based Monte Carlo simulation strategy. We compared the early time-gate reconstructions obtained with the different p (p is an element of{1/16; 1/8; 1/4; 1/3; 1/2; 1,2}) from a synthetic murine model simulating the fluorophore uptake in the kidneys and preclinical data. The results from a 3D mouse atlas and a mouse experiment show that our L-1/4 regularization methods give the best performance for early time gates reconstructions. (C) 2014 Optical Society of America
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