Abstract
The exposure to sun radiation is indispensable to our health; however, a long-term and high exposure could lead to cell damage, erythema, premature skin aging, and promotion of skin tumors. An underlying pathomechanism is the formation of free radicals which may induce oxidative stress at elevated concentrations. Different skin models, such as porcine-, murine-, human- ex vivo skin, reconstructed human skin (RHS) and human skin in vivo, were investigated during and after irradiation using X- and L-band EPR spectroscopy within different spectral regions (UVC to NIR). The amount of radical formation was quantified with the spin probe PCA and the radical types were measured ex vivo with the spin trap DMPO. The radiation dose influences the types of radicals formed in the skin. While reactive oxygen species (ROS) are always pronounced at low doses, there is an increase in lipid oxygen species (LOS) at high doses. Furthermore, the radical types arise independent from the irradiation wavelength, whereas the general amount of radical formation differs with the irradiation wavelength. Heat pre-stressed porcine skin already starts with higher LOS values. Thus, the radical type ratio might be an indicator of stress and the reversal of ROS/LOS constitutes the point where positive stress turns into negative stress.Compared to light skin types, darker types produce less radicals in the ultraviolet, similar amounts in the visible and higher ones in the infrared spectral region, rendering skin type-specific sun protection a necessity.
Highlights
The skin is the primary interface between the body and the environment and is permanently exposed to physical, chemical, and biological environmental influences, such as solar radiation or pollution
This review focuses on the effects of oxidative stress induced especially by irradiation with light of different wavelengths in different skin models and types as well as further applications, whereby the Electron paramagnetic resonance (EPR) technology is the main examination method
Exemplary spectra of the simulated radical species are shown: the hydroxyl radicals (DMPO/OH) defined as reactive oxygen species (ROS, red), the DMPO/CH3 abbreviated as C-centered radicals (CCR, gray), and the two alkoxyl species mentioned as lipid oxygen species (LOS, orange) spectroscopy provides more specific and sensitive results than fluorescence-based methods; using silver nanoparticles, it was demonstrated for the first time in vitro that the EPR technology is a more sensitive detection method for ROS production in cells compared to the fluorogenic dichlorofluorescein (DCF) assay (Ahlberg et al 2016)
Summary
The skin is the primary interface between the body and the environment and is permanently exposed to physical, chemical, and biological environmental influences, such as solar radiation or pollution. A too high dose of solar radiation leads to the excessive formation of free radicals. Free radicals are atoms or molecules that possess one or more unpaired free electrons and represent unstable, short-lived, and highly reactive molecules (Di Meo and Venditti 2020). They strive to compensate for their unstable state by wresting electrons from other molecules. The most important classes of free radicals in biological systems. The primary ROS are very reactive and interact with lipids, DNA, and proteins in the microenvironment. With regard to the skin physiology, ROS significantly contribute to the development of erythema, sunburn, inflammatory skin diseases, immunosuppression, skin cancer, and premature skin aging (Okayama 2005; Li et al 2016)
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