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Induced responses of Gnaphalium vira-vira and Gnaphalium luteo-album to UV-B radiationBurgueno, Pedro Osvaldo Cuadra January 1996 (has links)
No description available.
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Mechanisms underlying UVR-induced melanogenesisCarsberg, Catherine Jane January 1994 (has links)
No description available.
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Gene expression studied by in situ hybridization in cutaneous neoplasia and following insult to skinSmith, Martin Damian January 1994 (has links)
No description available.
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Assay of DNA photoproductsBowden, Gemma M. January 1995 (has links)
No description available.
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Hyperspectral imaging using ultraviolet lightPorter, Michael A. 12 1900 (has links)
The LINEATE IMAGING NEAR ULTRAVIOLET SPECTROMETER (LINUS) instrument has been used to remotely detect and measure sulfur dioxide (SO2). The sensor was calibrated in the lab, with curves of growth created for the 0.29 0.31 æ - spectral range of the LINUS sensor. Field observations were made of a coal burning plant in St. Johnâ s, Arizona at a range of 537 m. The Salt River Coronado plant stacks were emitting on average about 100 ppm and 200 ppm from the left and right stacks respectively. Analysis of the LINUS data matched those values within a few percent. Possible uses for this technology include remote verification of industry emissions and detection of unreported SO2 sources.
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The pathophysiology of UVA-light induced hyperalgesiaThemistocleus, Andreas Constantinos 08 September 2009 (has links)
D.Phil. Faculty of Health Sciences, University of the Witwatersrand, 2009 / In this thesis I describe the development of an animal model of sustained hyperalgesia
induced by exposure to ultraviolet (UV) A light to the rat’s tail, and the role of the Cfibre
barrage and peripheral afferent fibre sensitization in this model of hyperalgesia.
Exposure of rats’ tails to UVA-light caused hyperalgesia to a noxious thermal
challenge, immersion of the rats’ tails into 49°C water, and a noxious mechanical
challenge, application of a static force of 3.9N by a bar algometer onto the rats’ tails.
The hyperalgesia to the thermal challenge lasted eight days and hyperalgesia to the
mechanical challenge continued for up to 16 days. Despite the sustained hyperalgesia,
rats exposed to UVA-light showed no overt signs of morbidity as they gained weight
normally and were mobile throughout the study. Histological examination of rat tail
tissue showed mild, chronic inflammation in rats exposed to UVA-light and in rats that
had their tails covered with a protective layer of aluminium foil during UVA-light
exposure. This inflammation was therefore not responsible for the behavioural
hyperalgesia.
To investigate the role of C-fibre barrage in the development of hyperalgesia after
UVA-light exposure, I pre-emptively blocked C-fibre activation during UVA-light
exposure with the local anaesthetic bupivacaine. Injection of bupivacaine (1ml of
0.5%), into the base of the tail prevented the development of thermal hyperalgesia to
tail immersion in 49°C water. However, it did not prevent the development of
hyperalgesia to a noxious punctate challenge. Thus the sustained mechanical
hyperalgesia did not depend on the activation of the C-fibre barrage, but thermal
hyperalgesia did depend on the activation of a C-fibre barrage during the conditioning
event of UVA-light exposure.
Lastly, in rats anaesthetised with enflurane, I examined the responses of coccygeal
primary afferent fibres to noxious thermal and mechanical stimulation after UVA-light
exposure of their receptive fields on the tail. I investigated only pure nociceptive
afferents and ignored those afferents that responded to challenges in the noxious and
non-noxious ranges. The peak firing rates and areas under the curve of post-challenge
histograms, a measure of neuronal firing over time, of Ad- and C-fibres were
increased when noxious blunt and punctate challenges were applied to the rats’ tails
after UVA-light exposure, showing that Ad- and C-fibres that encode for noxious
mechanical challenges were sensitized. The peak firing rate of C-fibres that were
responsive to noxious thermal challenges were not increased after UVA-light
exposure. Therefore, thermal hyperalgesia was probably mediated by sensitization of
central nervous system neurones.
In summary, I developed a model of sustained mechanical and thermal hyperalgesia
caused by UVA-light exposure of the rat tail. The thermal hyperalgesia was initiated
by the C-fibre barrage, while mechanical hyperalgesia did not depend on the C-fibre
barrage and peripheral afferent sensitization of Ad- and C-fibres could account for the
mechanical hyperalgesia.
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Improvement of Ultraviolet Protection of Polyester Nonwoven -A Study of Volvos Parcel ShelvesLUNDIN, ELIN, HÄGG TURESSON, MIKAELA January 2014 (has links)
The parcel shelf in a car is one of the things that are most exposed to ultraviolet light and heat. The sunlight causes ultraviolet radiation and excessive heat to this area. This can cause the material to degrade, fade or drift in colour. The parcel shelf production is today divided between three producers. This requires a good contact and cooperation between the different actors. As the automobile industry is a very complex industry, high demand is required of everyone involved. The goal of this study was to find improvements that could lead to a better ultraviolet and heat protection. Volvo Cars provided material and the experiments were held on their test facility. The tests were conducted based on the Volvo Cars requirements and methods. A Weather-Ometer is used to simulate the ultraviolet light and heat, the same way a parcel shelf is exposed to outdoors. Chemical analyses are used to determine whether there is any difference in the material when it is aged in a Weather-Ometer or not. The parcel shelf is made of needle punched, dispersed dyed polyester. The results showed that the present parcel shelf material does indeed show a colour shift after ageing. The authors present a number of suggestions to improve the material's characteristics. For example, Volvo could consider using an acrylic non-woven instead of polyester. Dyes that withstand ultraviolet radiation better can also be chosen and a variety of ultraviolet absorbers can be added. 2-(2-hydroxy-5-carboxy-phenyl)-2H-benzotriazole, Tinuvin P, 327 [2-(2-hydroxy-5-methyl-phenyl) 2H-benzotriazole, 2-(3,5-butyl-6-hydroxy)-2H-2-chloro-benzotriazole respectively] and 2,4-dihydroxy-benzophenone are example of absorbers that can be added to make the ultraviolet resistance better. / Program: Textilingenjörsutbildningen
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Deep ultraviolet solid-state laser development /Dutton, David A. January 1900 (has links)
Thesis (M.S.)--Oregon State University, 2007. / Printout. Includes bibliographical references (leaves 71-72). Also available on the World Wide Web.
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The ultraviolet absorption spectra of lignin and related compoundsGlading, Ralph E. (Ralph Edmond) 01 January 1940 (has links)
No description available.
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The action of ultraviolet light on ligninForman, Loren Verne January 1940 (has links)
No description available.
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