Abstract
The fluorescence of Intralipid and polystyrene microspheres with sphere diameter of 1 µm at a representative lipid and microsphere concentration for simulation of mucosal tissue scattering has not been a subject of extensive experimental study. In order to elucidate the quantitative relationship between lipid and microsphere concentration and the respective fluorescent intensity, the extrinsic fluorescence spectra between 360 nm and 650 nm (step size of 5 nm) were measured at different lipid concentrations (from 0.25% to 5%) and different microsphere concentrations (0.00364, 0.0073, 0.0131 spheres per cubic micrometer) using laser excitation at 355 nm with pulse energy of 2.8 µJ. Current findings indicated that Intralipid has a broadband emission between 360 and 650 nm with a primary peak at 500 nm and a secondary peak at 450 nm while polystyrene microspheres have a single peak at 500 nm. In addition, for similar scattering properties the fluorescence of Intralipid solutions is approximately three-fold stronger than that of the microsphere solutions. Furthermore, Intralipid phantoms with lipid concentrations ~2% (simulating the bottom layer of mucosa) produce up to seven times stronger fluorescent emission than phantoms with lipid concentration ~0.25% (simulating the top layer of mucosa). The fluoresence decays of Intralipid and microsphere solutions were also recorded for estimation of fluorescence lifetime.
Highlights
Mucosal tissues in the oral cavity, pharynx, esophagus, and digestive system are targets of mucosal cancer, which is responsible for approximately 200,000 deaths annually in the United States [1]
Simulating scattering of the stromal layer of the mucosa is important in optical phantoms which attempt to mimic mucosal tissues
3.1 Scattering of phantoms compared to mucosal tissues
Summary
Mucosal tissues in the oral cavity, pharynx, esophagus, and digestive system are targets of mucosal cancer, which is responsible for approximately 200,000 deaths annually in the United States [1]. Various optical biopsy methods have been investigated as potential minimally-invasive techniques for early diagnosis and treatment [2,3,4]. In these studies, phantoms simulating key tissue optical properties (e.g. absorption and scattering coefficients) are extensively used in developing theoretical models [2,3,4]. Mucosal tissues have two distinguished layers – the epithelium on top of the stromal layer [5,6]. Simulating scattering of the stromal layer of the mucosa is important in optical phantoms which attempt to mimic mucosal tissues
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