Mechanism and Biological Relevance of Blue-light (420-453 Nm)-induced Nonenzymatic Nitric Oxide Generation from Photolabile Nitric Oxide Derivates in Human Skin in Vitro and in Vivo

Overview

Journal Free Radic Biol Med

Specialties Biochemistry
Biology
General Medicine

Date 2013 Oct 15

PMID 24121056

Citations 27

Authors

Christian Oplander

Annika Deck

Christine M Volkmar

Michael Kirsch

Jorg Liebmann

Matthias Born

Frank van Abeelen

Ernst E van Faassen

Klaus-Dietrich Kroncke

Joachim Windolf

Christoph V Suschek

Affiliations

Soon will be listed here.

Abstract

Human skin contains photolabile nitric oxide (NO) derivates such as nitrite and S-nitrosothiols, which upon UVA radiation decompose under high-output NO formation and exert NO-specific biological responses such as increased local blood flow or reduced blood pressure. To avoid the injurious effects of UVA radiation, we here investigated the mechanism and biological relevance of blue-light (420-453 nm)-induced nonenzymatic NO generation from photolabile nitric oxide derivates in human skin in vitro and in vivo. As quantified by chemiluminescence detection (CLD), at physiological pH blue light at 420 or 453 nm induced a significant NO formation from S-nitrosoalbumin and also from aqueous nitrite solutions by a to-date not entirely identified Cu(1+)-dependent mechanism. As detected by electron paramagnetic resonance spectrometry in vitro with human skin specimens, blue light irradiation significantly increased the intradermal levels of free NO. As detected by CLD in vivo in healthy volunteers, irradiation of human skin with blue light induced a significant emanation of NO from the irradiated skin area as well as a significant translocation of NO from the skin surface into the underlying tissue. In parallel, blue light irradiation caused a rapid and significant rise in local cutaneous blood flow as detected noninvasively by using micro-light-guide spectrophotometry. Irradiation of human skin with moderate doses of blue light caused a significant increase in enzyme-independent cutaneous NO formation as well as NO-dependent local biological responses, i.e., increased blood flow. The effects were attributed to blue-light-induced release of NO from cutaneous photolabile NO derivates. Thus, in contrast to UVA, blue-light-induced NO generation might be therapeutically used in the treatment of systemic and local hemodynamic disorders that are based on impaired physiological NO production or bioavailability.

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