Global ETD Search

291	UV-Induced DNA Damage and Repair: The Role of Melanin and the MC1R Gene Hauser, Jennifer E. 03 April 2006 (has links) No description available. Biology, Cell melanoma human melanocytes ultraviolet radiation melanin eumelanin melanocortin 1 receptor cyclobutane pyrimide dimers
292	Cause and Consequences of Spatial Dynamics of Planktonic Organisms in Lake Ecosystems Leach, Taylor Hepburn 29 November 2016 (has links) No description available. Ecology Limnology
293	Control of <i>Salmonella Enterica</i> serovar enteritidis in shell eggs by ozone, ultraviolet radiation, and heat Rodriguez Romo, Luis Alberto 10 March 2004 (has links) No description available. Salmonella Shell eggs Ozone Ultraviolet radiation Egg pasteurization Egg safety Thermal inactivation of Salmonella Sanitizers Synergy
294	Examining student understanding of the science of a societal issue in Botswana: Effects of ultraviolet radiation on the human skin Suping, Shanah Mompoloki 21 June 2004 (has links) No description available. Science education Science education reform Science education in Botswana Curriculum reform
295	Molecular Responses to Environmental Stress in Temperate and Polar Flies Lopez-Martinez, Giancarlo 24 June 2008 (has links) No description available. Entomology Belgica antarctica Rhagoletis pomonella SOD catalase heat shock proteins ultraviolet radiation diapause
296	Prostaglandin-E2 is produced by adult human epidermal melanocytes in response to UVB in a melanogenesis-independent manner. Gledhill, Karl, Rhodes, L.E., Brownrigg, M., Haylett, A.K., Masoodi, Mojgan, Thody, Anthony J., Nicolaou, Anna, Tobin, Desmond J. January 2010 (has links) No / Erythema occurs in human skin following excessive exposure to ultraviolet radiation (UVR), and this is in part mediated by the vasodilator prostaglandin E2 (PGE2). While keratinocytes are a major source of this pro-inflammatory eicosanoid, epidermal melanocytes (EM) also express some of the cellular machinery required for PGE2 production. The primary aim of this study is to determine whether EM can produce PGE2 and so potentially also contribute to UVR-induced skin inflammation. Furthermore, we investigate the likely pathway by which this PGE2 production is achieved and investigate whether PGE2 production by EM is correlated with melanogenic capacity. Primary cultures of EM were established from nine normal healthy individuals with skin phototype-1 (n=4) and 4 (n=5), and PGE2 production and melanogenic status were assessed. EM produced PGE2 under baseline conditions and this was increased further upon stimulation with arachidonic acid. Moreover, EM expressed cytoplasmic phospholipase A2, cyclooxygenase-1 and cytoplasmic prostaglandin E synthase. However, no EM culture expressed cyclooxygenase-2 under baseline conditions or following arachidonic acid, UVB- or H2O2 treatments. PGE2 production in response to UVB was highly variable in EM cultures derived from different donors but when pooled for skin phototype exhibited a positive correlation only with SPT-1 derived EM. Interestingly, PGE2 production by EM in response to UVB showed no correlation with baseline levels of melanin, tyrosinase expression/activity or tyrosinase-related protein-1 expression. However, there was an apparent negative correlation with baseline expression of dopachrome tautomerase (DCT), a melanogenic enzyme with reported anti-oxidant potential. These findings suggest that EM have the potential to contribute to UVR-induced erythema via PGE2 production, but that this response may be more related to oxidative stress than to their melanogenesis status. / The Wellcome Trust Epidermal melanocyte Ultraviolet radiation (UVR) Prostaglandin E2 Cyclooxygenase Dopachrome tautomerase Melanogenesis Skin phototype Erythema
297	The eicosanoid response to high dose UVR exposure of individuals prone and resistant to sunburn Nicolaou, Anna, Masoodi, Mojgan, Gledhill, Karl, Haylett, A.K., Thody, Anthony J., Tobin, Desmond J., Rhodes, L.E. January 2012 (has links) No / High personal UVR doses can be gained during leisure activities, causing intense self-resolving inflammation (sunburn) of unprotected skin. UVR activates release of membrane fatty acids and upregulates their metabolism by cyclooxygenases (COX) and lipoxygenases (LOX) to different eicosanoids. While COX-derived prostaglandin (PG)E2 is a potent mediator of sunburn vasodilatation, LOX-derived 15-hydroxyeicosatetraenoic acid (HETE) and its lipoxin metabolites may contribute to sunburn limitation. We explored the relationships between expression of these lipid mediators and the clinical and histological outcomes, comparing responses of individuals prone and more resistant to sunburn. An acute UVR exposure of 12 SED (standard erythema dose) was applied to buttock skin of 32 white Caucasians (n = 16 phototype I/II, n = 16 phototype III/IV), and over the subsequent 72 h assessments were made of skin erythema, immunohistochemical expression of leukocyte markers, COX-2, 12-LOX, 15-LOX and nitric oxide synthase (NOS), and eicosanoid levels by LC/ESI-MS/MS. Evidence of a significant inflammatory response was seen earlier in phototype I/II with regard to expression of erythema (4h, p < 0.001), neutrophil infiltration (24 h, p = 0.01), epidermal COX-2 (24 h, p < 0.05) and 12-LOX (24 h, p < 0.01), and dermal eNOS (24 h, p < 0.05) proteins, although CD3+ lymphocyte infiltration showed an earlier increase in phototype III/IV (24 h, p < 0.05). Although erythema was equivalent at 72 h in both groups, phototype I/II showed higher PGE2 accompanied by elevated 15-HETE, and a strong positive correlation was seen between these mediators (n = 18, r = 0.805, p = 0.0001). Hence anti-inflammatory eicosanoid 15-HETE may temper the pro-inflammatory milieu in sunburn, having greater influence in those prone to sunburn than those more resistant, given the same high UVR exposure conditions. / The Wellcome Trust Solar ultraviolet radiation (UVR) Sunburn Eicosanoids Lipidomics Cutaneous eicosanoids
298	Randomized controlled trial of oral omega-3 PUFA in solar-simulated radiation-induced suppression of human cutaneous immune responses. Pilkington, S.M., Massey, Karen A., Bennett, S.P., Al-Aasswad, Naser M.I., Roshdy, K., Gibbs, N.K., Friedmann, P.S., Nicolaou, Anna, Rhodes, L.E. 30 January 2013 (has links) No / Background: Skin cancer is a major public health concern, and the majority of cases are caused by solar ultraviolet radiation (UVR) exposure, which suppresses skin immunity. Omega-3 (n−3) PUFAs protect against photoimmunosuppression and skin cancer in mice, but the impact in humans is unknown. Objectives: We hypothesized that EPA-rich n−3 PUFA would abrogate photoimmunosuppression in humans. Therefore, a nutritional study was performed to assess the effect on UVR suppression of cutaneous cell-mediated immunity (CMI) reflected by nickel contact hypersensitivity (CHS). Design: In a double-blind, randomized controlled study, 79 volunteers (nickel-allergic women, 22–60 y old, with phototype I or II) took 5 g n−3 PUFA–containing lipid (70% EPA plus 10% DHA) or a control lipid daily for 3 mo. After supplementation, nickel was applied to 3 skin sites preexposed on 3 consecutive days to 1.9, 3.8, or 7.6 J/cm2 of solar-simulated radiation (SSR) and to 3 unexposed control sites. Nickel CHS responses were quantified after 72 h and the percentage of immunosuppression by SSR was calculated. Erythrocyte [red blood cell (RBC)] EPA was measured by using gas chromatography. Results: SSR dose-related suppression of the nickel CHS response was observed in both groups. Photoimmunosuppression appeared less in the n−3 PUFA group than in the control group (not statistically significant [mean difference (95% CI): 6.9% (−2.1%, 15.9%)]). The difference was greatest at 3.8 J/cm2 SSR [mean difference: 11% (95% CI: 0.5%, 21.4%)]. Postsupplementation RBC EPA was 4-fold higher in the n−3 PUFA group than in the control group (mean difference: 2.69% (95% CI: 2.23%, 3.14%), which confirmed the EPA bioavailability. Conclusion: Oral n−3 PUFAs appear to abrogate photoimmunosuppression in human skin, providing additional support for their chemopreventive role; verification of study findings is required. Omega-3 PUFA Human cutaneous immune responses Photoimmunosuppression
299	Evaluation of the effects of solar ultraviolet radiation on the growth of vibrio cholerae and on the secretion of the cholera toxin Ssemakalu, Cornelius Cano 09 1900 (has links) Cholera is a water-borne disease that continues to ravage resource poor communities around the world especially those in developing countries. The disease is caused by Vibrio cholerae microorganisms whose natural habitat is the aquatic ecosystem. It is believed that this microorganism prior to becoming the primary cause of cholera acquired virulence factors expressed by two separate genetic elements. These genetic elements are known as VPIФ and CTXФ were acquired in that order for known physiological reasons. However only V. cholerae in possession of the CTX genetic element are capable of causing cholera disease. At present only two serotypes are known to have the ability to cause cholera and these are V. cholerae serotypes O1 and O139. SODIS (Solar disinfection) is an extremely low cost refined technology that can be used for the disinfection of water especially in areas where there is a considerable amount of sunshine. Although this technology is a composite of various factors the underlying principle is the use of solar ultraviolet radiation (SUVR). The preliminary target of SUVR is the cytoplasmic membrane and this was confirmed by flow cytometric analysis. The consequences of leaky cytoplasmic membrane include cellular death to the microorganism as well as an increase in cholera toxin secretion. The main objective of this study was to investigate the effect of solar ultraviolet radiation on the growth of V. cholerae and on the secretion of cholera toxin and to provide supporting information for the use of SODIS in South Africa while observing the possible role that climate may play in the onset of cholera disease. The initial part of the study evaluated the culturability, biomass increase and cholera toxin secretion in both a nutrient poor and a nutrient rich media by two toxigenic and one non toxigenic strain of V. cholerae. A series of pH and temperature combinations were used to achieve this objective. The result revealed that the microorganisms survived in both media. An increase in biomass was observed for all the bacteria grown in the nutrient rich media whereas in the poor nutrient media the bacteria remained culturable but no increase in biomass was observed. Interestingly lower temperatures seemed to provide more optimal growth conditions while high temperature on most occasions favoured cholera toxin secretion, in both media.The second part of the study required the exposure of the microorganisms to SUVR. A SODIS approach was used with a few modifications. The V. cholerae strains were exposed to solar radiation during all the seasons of the year. Evaluation of the viability, the increase in biomass and the detection of cholera toxin secretion was determined after each exposure to solar radiation. The results seem to suggest that the effect of SUVR depended on the season of the year, the nature of the media, strain, solar conditions and in the duration of solar exposure, in no particular order. The secretion of cholera toxin was mainly dependent on the media used, the season of the year and on the serotype of the strain. This study represents the first report on the evaluation of SUVR for the disinfection of water under South African conditions (Pretoria area) during all seasons of the year with variations in solar radiation levels and temperature. Furthermore what actually happened to V. cholerae during solar exposure in terms of cell morphology, cell viability and secretion of cholera toxin is also reported and this can give an insight of the possible role that SUVR may play in the onset of cholera. The main recommendation emanating from this study is the sensitisation of communities worldwide about the capacity that, SUVR carries to lighten the burden of communicable water borne diseases especially, in resource limited areas through the implementation of SODIS. / Life and Consumer Sciences / M. Sc. (Life Science) 614.5140968 Vibrio cholerae -- South Africa Cholera toxin -- South Africa Solar radiation -- South Africa Ultraviolet radiation -- South Africa
300	Caspase-3 in lens epithelium Talebizadeh, Nooshin January 2016 (has links) Purpose: To model the time evolution of active caspase-3 protein expression in a healthy lens, and in a lens exposed to UVR-300 nm (UVR-B). To develop an automated method to classify the fluorescent signal of biomarkers in the lens epithelial cells. Methods: Six-week old Sprague-Dawley rats were used. Firstly, expression of active caspase-3 was studied in the lens epithelium of healthy rats. Secondly, rats were unilaterally exposed in vivo to 1 kJ/m2 UVR-B for 15 minutes. At 0.5, 8, 16, and 24 hours after the UVR-B exposure, the exposed and the contralateral non-exposed lenses were removed. Immunohistochemistry was done on three mid-sagittal sections from each lens. The florescent labelling for active caspase-3 in each lens section was counted three times. The time evolution of active caspase-3 expression in response to UVR-B exposure was modelled as a function of cell position in the lens epithelium. An automated objective method was developed to quantify the lens epithelial cells and to classify the fluorescent signal of active caspase-3. Active caspase-3 was selected as a model signal. Results: Active caspase-3 was abundant in the anterior pole of the normal lenses. Spatial distribution of active caspase-3 labelling in the lens epithelium was fitted to a logistic model. The probability of active caspase-3 expression was higher in the UVR-B exposed lenses (95% CI = 0.12 ± 0.01). There was no difference in the expression of active caspase-3 between the 0.5 and the 24 hours groups or between the 8 and the 16 hours groups. A difference was noted, when comparing the 0.5 and 24 hours groups with the 8 and 16 hours groups (Test statistic 7.01, F1;36;0.95= 4.11). Exposure to UVR-B has an impact on the average probability of labelling for active caspase-3 as a function of cell position. The probability of labelling as a function of cell number also varied as a function of time after UVR-B exposure. The automated method counted the lens epithelial cells and estimated the proportion of active caspase-3 labelling in the lens epithelium. Conclusions: Active caspase-3 is present in the healthy lens epithelial cells. Active caspase-3 exhibits higher expression at the anterior pole of the lens and the expression decreases towards the periphery. After UVR-B exposure, the expression of active caspase-3 in the lens epithelium increases with a peak of expression occurring around 16 hours after exposure. The average probability of labelling in the lens epithelium is dependent on both the UVR-B exposure and the time period elapsed after the exposure. The automated method enables objective and fast quantification of lens epithelial cells and the expression of fluorescent signal in the lens cells. ultraviolet radiation caspase-3 lens cataract apoptosis Immunohistochemistry spatial distribution time evolution modelling automatic analysis cell counting image analysis.

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