Abstract
In this paper, we demonstrate that a scanning MEMS mirror can be employed to create a linear gradient line source that is equivalent to a planar source. This light source setup facilitates the use of diffusion models of increased orders of approximation having closed form solution, and thus enhance the efficiency and accuracy in sample optical properties recovery. In addition, compared with a regular planar light source, the linear gradient line source occupies much less source area and has an elevated measurement efficiency. We employed a δ-P1 diffusion equation with a closed form solution and carried out a phantom study to understand the performance of this new method in determining the absorption and scattering properties of turbid samples. Moreover, our Monte Carlo simulation results indicated that this geometry had probing depths comparable to those of the conventional diffuse reflectance measurement geometry with a source-detector separation of 3 mm. We expect that this new source setup would facilitate the investigating of superficial volumes of turbid samples in the wavelength regions where tissue absorption coefficients are comparable to scattering coefficients.
Highlights
In recent years, Diffuse Reflectance Spectroscopy (DRS) techniques have been developed rapidly and widely used for many biomedical applications [1,2,3,4]
Because the linear gradient line source illumination (LGLSI) geometry has a more localized probing volume compared to the planar source illumination (PSI) geometry, it would be less affected by the tissue surface flatness and be more sensitive to the presence of an abnormal inhomogeneity
The detection fiber does not block a part of illumination in the LGLSI geometry as it does in the PSI geometry; the repeatability in the LGLSI geometry is better than that in the PSI counterpart
Summary
Diffuse Reflectance Spectroscopy (DRS) techniques have been developed rapidly and widely used for many biomedical applications [1,2,3,4]. In a typical DRS configuration, light is injected into the sample under investigation and the diffuse reflectance is noninvasively detected at a distance from the source. The optical properties of the sample, including absorption (μa) and reduced scattering (μs') coefficients, can be deduced from the measured diffuse reflectance, and these parameters can in turn provide ample information on a variety of physiological processes [1, 2, 5,6,7]. DRS techniques rely on a photon transport model to relate the optical properties of samples to the diffuse reflectance. DRS techniques that work with the SDE are usually applied to study highly scattering thick tissue, such as breast or brain, in the 600 to 1000 nm wavelength region and at large source-detector separations [4, 13, 14]
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