Abstract
The knowledge of the optical properties of biological tissues in a wide spectral range is highly important for the development of noninvasive diagnostic or treatment procedures. The absorption coefficient is one of those properties, from which various information about tissue components can be retrieved. Using transmittance and reflectance spectral measurements acquired from ex vivo rabbit brain cortex samples allowed to calculate its optical properties in the ultraviolet to the near infrared spectral range. Melanin and lipofuscin, the two pigments that are related to the aging of tissues and cells were identified in the cortex absorption. By subtracting the absorption of these pigments from the absorption of the brain cortex, it was possible to evaluate the true ratios for the DNA/RNA and hemoglobin bands in the cortex—12.33-fold (at 260 nm), 12.02-fold (at 411 nm) and 4.47-fold (at 555 nm). Since melanin and lipofuscin accumulation increases with the aging of the brain tissues and are related to the degeneration of neurons and their death, further studies should be performed to evaluate the evolution of pigment accumulation in the brain, so that new optical methods can be developed to aid in the diagnosis and monitoring of brain diseases.
Highlights
The optical properties of biological tissues are unique to those tissues and provide means for their identification
The results obtained in this study are to others that have been reported for different biological tissues
An analysis on the absorption of the cortex showed that it contains some pigments, namely melanin and lipofuscin, which hides the true content of other biological absorbers that the tissue contains
Summary
The optical properties of biological tissues are unique to those tissues and provide means for their identification. Some diagnostic or treatment windows have been previously identified in the visible and infrared range of the electromagnetic spectrum [6,7], current biophotonics techniques can be applied within different spectral bands from the deep ultraviolet to the terahertz [8]. This means that a fast way to obtain the optical properties of a tissue for a wide spectral range is necessary.
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