Abstract
Simple SummaryPhotobiomodulation studies have reported that blue light irradiation induces the production of reactive oxygen species. We examined the effect of blue laser (405 nm) irradiation on ATP level in the skin and measured the types of reactive oxygen species and reactive nitrogen species. The decrease in the skin ATP level due to blue light irradiation may be caused by oxidative stress due to the generation of reactive oxygen species. These findings highlight the need to consider the effects on the skin when performing photobiomodulation treatment using blue light.Photobiomodulation studies have reported that blue light irradiation induces the production of reactive oxygen species. We investigated the effect of blue laser (405 nm) irradiation on the ATP levels in mouse skin and determined the types of reactive oxygen species and reactive nitrogen species using cultured mouse fibroblasts. Blue laser irradiation caused a decrease in the ATP level in the mouse skin and triggered the generation of superoxide anion and hypochlorous acid, whereas nitric oxide and peroxynitrite were not detected. Moreover, blue laser irradiation resulted in reduced cell viability. It is believed that the decrease in the skin ATP level due to blue light irradiation results from the increased levels of oxidative stress due to the generation of reactive oxygen species. This method of systematically measuring the levels of reactive oxygen species and reactive nitrogen species may be useful for understanding the effects of irradiation conditions.
Highlights
Publisher’s Note: MDPI stays neutralUnder appropriate conditions, visible to near-infrared light irradiation exerts woundhealing, anti-inflammatory, anti-edema, and hair growth-promoting effects [1]
In the treatment of acne vulgaris caused by Cutibacterium acnes, coproporphyrin III, a metabolite of C. acnes, acts as a photosensitizer
We aimed to identify the types of Reactive oxygen species (ROS) and reactive nitrogen species (RNS) produced in response to blue laser irradiation in fibroblasts using multiple fluorescent probes
Summary
Visible to near-infrared light irradiation exerts woundhealing, anti-inflammatory, anti-edema, and hair growth-promoting effects [1]. Light sources with wavelengths in the 400 nm range are used to treat psoriasis vulgaris, prurigo vulgaris, and atopy, as well as for tooth bleaching and restoration procedures involving composite resin [2,3,4]. In the treatment of acne vulgaris caused by Cutibacterium acnes, coproporphyrin III, a metabolite of C. acnes, acts as a photosensitizer. Reactive oxygen species (ROS) generated by irradiation with blue light can treat acne by sterilization [5].
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