Abstract
Current biophotonics methods cover the entire optical spectrum from the deep ultraviolet to the terahertz. To optimize such methods for diagnostic and therapeutic applications, the need to obtain the wideband dispersion of tissues is high. The pancreas is a very important organ in the human body, since it produces insulin and its malfunction may induce diabetes. A reduced number of biophotonics publications regarding the pancreas is available, meaning that studies to determine its optical properties and their variation during optical clearing treatments are necessary. Considering this fact, we used the total internal reflection method to measure the refractive index of the rabbit pancreas for wavelengths between 400 and 850 nm. The experimental results allowed to calculate the pancreas dispersion with the Cauchy, Conrady and Cornu equations. It was observed that all those equations provided good data fitting in the spectral range of the measurements, but differences were observed outside these limits. Considering the wavelength of 633 nm, the mean value from the three dispersions was 1.3521, while the one published for porcine pancreas is 1.3517. The dispersion calculated with the Conrady equation does not present a fast decreasing behavior for shorter wavelengths as the ones calculated with the Cauchy and Cornu equations, but comparing these curves with a dispersion for a tissue-like material, all seem to have good agreement.
Highlights
Among the various optical properties of biological tissues, the refractive index (RI) is one of the most important and fundamental, since it can be used for many biophotonics applications
Clinical applications of light can be made at various wavelengths within a very wide spectral range that goes from the deep ultraviolet (UV) to the terahertz (THz) [11]
The evaluation of tissues’ dispersions is of great interest for the application of optical clearing (OC) treatments, since the exchange of interstitial tissue water by an optical clearing agent (OCA) induces RI variations that will be responsible for the light scattering decrease and consequent increase in tissue transparency [12]
Summary
Among the various optical properties of biological tissues, the refractive index (RI) is one of the most important and fundamental, since it can be used for many biophotonics applications. The evaluation of tissues’ dispersions is of great interest for the application of optical clearing (OC) treatments, since the exchange of interstitial tissue water by an optical clearing agent (OCA) induces RI variations that will be responsible for the light scattering decrease and consequent increase in tissue transparency [12]. For such particular application, the knowledge of the tissue dispersion and of the dispersions of its components is highly important [13, 14]
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