Ultraviolet erythema: dose response and mediator diffusion

The earliest contribution made by Jan van der Leun to the field of photobiology was studying the mechanism of UV-induced erythema in human skin - a subject he chose for his PhD in the 1960s. His contribution to this topic encouraged us to continue this work and over a number of years in the 1980s an...

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Veröffentlicht in:	Photochemical & photobiological sciences 2018, Vol.17 (12), p.1941-1945
Hauptverfasser:	Diffey, Brian L, Farr, Peter M
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Sprache:	eng
Schlagworte:	Biochemistry Biomaterials Blood vessels Chemistry Diffusion Diffusion theory Dose-Response Relationship, Radiation Epidermis Erythema Erythema - etiology Erythema - metabolism Humans Models, Theoretical Physical Chemistry Plant Sciences Skin Skin - radiation effects Ultraviolet radiation Ultraviolet Rays - adverse effects Wavelengths
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container_title	Photochemical & photobiological sciences
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creator	Diffey, Brian L Farr, Peter M
description	The earliest contribution made by Jan van der Leun to the field of photobiology was studying the mechanism of UV-induced erythema in human skin - a subject he chose for his PhD in the 1960s. His contribution to this topic encouraged us to continue this work and over a number of years in the 1980s and 1990s, we carried out several studies on quantitative aspects of UV erythema. A major part of Jan's thesis focused on diffusion processes in UV erythema and his observations led him to conclude that erythema induced by radiation with wavelengths of around 300 nm was due to the actions of a diffusing mediator arising in the epidermis, whereas radiation at shorter wavelengths around 254 nm, caused erythema by exerting a direct effect on the dermal blood vessels. By taking his data and combining them with our own studies on the dose response of UV erythema to radiation of different wavelengths, we were able to show that, contrary to Jan's conclusions, the mediator diffusion theory he developed did indeed predict that both UVB and UVC induced erythema could be explained by the action of diffusing mediators. The earliest contribution made by Jan van der Leun to the field of photobiology was studying the mechanism of UV-induced erythema in human skin - a subject he chose for his PhD in the 1960s.
doi_str_mv	10.1039/c7pp00228a
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His contribution to this topic encouraged us to continue this work and over a number of years in the 1980s and 1990s, we carried out several studies on quantitative aspects of UV erythema. A major part of Jan's thesis focused on diffusion processes in UV erythema and his observations led him to conclude that erythema induced by radiation with wavelengths of around 300 nm was due to the actions of a diffusing mediator arising in the epidermis, whereas radiation at shorter wavelengths around 254 nm, caused erythema by exerting a direct effect on the dermal blood vessels. By taking his data and combining them with our own studies on the dose response of UV erythema to radiation of different wavelengths, we were able to show that, contrary to Jan's conclusions, the mediator diffusion theory he developed did indeed predict that both UVB and UVC induced erythema could be explained by the action of diffusing mediators. 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subjects	Biochemistry Biomaterials Blood vessels Chemistry Diffusion Diffusion theory Dose-Response Relationship, Radiation Epidermis Erythema Erythema - etiology Erythema - metabolism Humans Models, Theoretical Physical Chemistry Plant Sciences Skin Skin - radiation effects Ultraviolet radiation Ultraviolet Rays - adverse effects Wavelengths
title	Ultraviolet erythema: dose response and mediator diffusion
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