Your search keyword '"Villette T"' showing total 12 results

1. Carbon and energy footprint of nonmetallic composite pipes in onshore oil and gas flowlines

Author

Zubail, A., Traidia, A., Masulli, M., Vatopoulos, K., Villette, T., and Taie, I.

Published

2021

2. Blue light exposure in vitro causes toxicity to trigeminal neurons and glia through increased superoxide and hydrogen peroxide generation

Author

Marek, V., Potey, A., Réaux-Le-Goazigo, A., Reboussin, E., Charbonnier, A., Villette, T., Baudouin, C., Rostène, W., Denoyer, A., and Mélik Parsadaniantz, S.

Published

2019

3. Customer satisfaction measurement: a how-to guide to contact center excellence

Author

Nolon, Villette T.

Subjects

Support services, Customer service, Outsourcing, Business plans -- Methods, Outsourcing -- Outsourcing -- Methods, Consumer behavior -- Methods, Business planning -- Methods, Customer satisfaction -- Methods, Customer service -- Methods

Abstract

The role of today's contact center is rapidly shifting. Expected to both support a company's global business strategy and play an integral part in the overall customer experience, the contact […]

Published

2005

4. 5-Aryl-β,γ butenolide, a new class of antibacterial derived from the N-aryl oxazolidinone DUP 721

Author

Denis, A. and Villette, T.

Published

1994

5. ChemInform Abstract: 5-Aryl-β,γ-butenolide, a New Class of Antibacterial Derived from the N-Aryl Oxazolidinone DUP 721.

Author

DENIS, A. and VILLETTE, T.

Published

1995

6. Prevention of Sunlight-Induced Cell Damage by Selective Blue-Violet-Light-Filtering Lenses in A2E-Loaded Retinal Pigment Epithelial Cells.

Author

Barrau C, Marie M, Ehrismann C, Gondouin P, Sahel JA, Villette T, and Picaud S

Abstract

Blue light accelerates retinal aging. Previous studies have indicated that wavelengths between 400 and 455 nm are most harmful to aging retinal pigment epithelia (RPE). This study explored whether filtering these wavelengths can protect cells exposed to broad sunlight. Primary porcine RPE cells loaded with 20 µM A2E were exposed to emulated sunlight filtered through eye media at 1.8 mW/cm 2 for 18 h. Filters selectively filtering out light over 400-455 nm and a dark-yellow filter were interposed. Cell damage was measured by apoptosis, hydrogen peroxide (H 2 O 2 ) production, and mitochondrial membrane potential (MMP). Sunlight exposure increased apoptosis by 2.7-fold and H 2 O 2 by 4.8-fold, and halved MMP compared to darkness. Eye Protect System TM (EPS) technology, filtering out 25% of wavelengths over 400-455 nm, reduced apoptosis by 44% and H 2 O 2 by 29%. The Multilayer Optical Film (MOF), at 80% of light filtered, reduced apoptosis by 91% and H 2 O 2 by 69%, and increased MMP by 73%, overpassing the dark-yellow filter. Photoprotection increased almost linearly with blue-violet light filtering (400-455 nm) but not with total blue filtering (400-500 nm). Selective filters filtering out 25% (EPS) to 80% (MOF) of blue-violet light offer substantial protection without affecting perception or non-visual functions, making them promising for preventing light-induced retinal damage with aesthetic acceptance for permanent wear.

Published

2024

7. Effects of mild- and moderate-intensity illumination on short-term axial length and choroidal thickness changes in young adults.

Author

Chakraborty R, Baranton K, Spiegel D, Lacan P, Guillon M, Barrau C, and Villette T

Subjects

Adult, Axial Length, Eye, Child, Choroid, Eyeglasses, Humans, Refraction, Ocular, Tomography, Optical Coherence methods, Young Adult, Lighting, Myopia etiology

Abstract

Purpose: Previous studies have shown that time spent outdoors is protective against myopia development in children. In this study, we examined the effects of 500 and 1000 lux of illumination to the eye on axial length (AL) and choroidal thickness (CT) changes in young adults., Methods: Fifteen participants (mean age, 21.60 years [2.16]) with a mean refraction of -0.34 D (0.37) were exposed to 500 and 1000 lux of illumination for 120 min in a dark room on two different days, using a pair of light-emitting glasses. Ocular measurements were repeated on an additional day in darkness (~5 lux). Ocular biometrics and CT were measured and analysed in the right eye before the light exposure (0 min), after 30, 60 and 120 min of exposure and 30 min after light offset to measure recovery using the Lenstar biometer and the Cirrus optical coherence tomographer, respectively., Results: Exposure to 500 and 1000 lux of illumination resulted in a significant reduction in AL at 30, 60 and 120 min compared to darkness (AL change at 120 min: darkness, +0.020 mm [0.004]; 500 lux, -0.006 mm [0.004]; 1000 lux, -0.013 mm [0.004]; p < 0.001). Exposure to 500 and 1000 lux caused a significant overall thickening of the subfoveal choroid compared to darkness (CT change across 120 min: darkness, -0.010 mm [0.007]; 500 lux, +0.006 mm [0.005]; 1000 lux, +0.009 mm [0.003], p = 0.02). Ocular changes were not significantly different between the two illumination levels (p > 0.05) and returned to baseline within 30 min of light offset., Conclusions: Exposure to mild- or moderate-intensity illumination on the eye can induce a significant short-term reduction in AL and an increase in CT in young adults. Future studies on larger cohorts with varying light intensities are needed to better understand the effects of ocular illumination on AL changes in humans., (© 2022 College of Optometrists.)

Published

2022

8. Blue-violet light decreases VEGFa production in an in vitro model of AMD.

Author

Marie M, Gondouin P, Pagan D, Barrau C, Villette T, Sahel J, and Picaud S

Subjects

Animals, Apoptosis, Cell Survival, Cells, Cultured, In Vitro Techniques, Macular Degeneration pathology, Retinal Pigment Epithelium radiation effects, Swine, Eye Proteins metabolism, Light, Macular Degeneration metabolism, Models, Biological, Retinal Pigment Epithelium metabolism, Vascular Endothelial Growth Factor A metabolism

Abstract

Blue light is an identified risk factor for age-related macular degeneration (AMD). The production of vascular endothelial growth factor (VEGF), leading to neovascularization, is a major complication of the wet form of this disease. We investigated how blue light affects VEGF expression and secretion using A2E-loaded retinal pigment epithelium (RPE) cells, a cell model of AMD. Incubation of RPE cells with A2E resulted in a significant increase in VEGF mRNA and, intracellular and secreted VEGF protein levels, but not mRNA levels of VEGFR1 or VEGFR2. Blue light exposure of A2E-loaded RPE cells resulted in a decrease in VEGF mRNA and protein levels, but an increase in VEGFR1 levels. The toxicity of 440 nm light on A2E-loaded RPE cells was enhanced by VEGF supplementation. Our results suggest that age-related A2E accumulation may result in VEGF synthesis and release. This synthesis of VEGF, which enhances blue light toxicity for the RPE cells, is itself suppressed by blue light. Anti-VEGF therapy may therefore improve RPE survival in AMD., Competing Interests: I have read the journal's policy and the authors of this manuscript have the following competing interests: CB and TV are Essilor employees. SP received fees for participating in a meeting organized by Essilor. SP received a grant from Essilor to work on light toxicity on retinal cells. No competing financial interests exist for PG, and DP. This does not alter our adherence to PLOS ONE policies on sharing data and materials. The authors would like to declare the following patents/patent applications associated with this research: EP2602655 : filtre ophtalmique; EP2602654 : filtre ophtalmique; EP2602653 : Méthode de la détermination de la configuration d'un filtre ophtalmique; EP19305328 : filter for eye cone cells protection.

Published

2019

9. Implication of Melanopsin and Trigeminal Neural Pathways in Blue Light Photosensitivity in vivo .

Author

Marek V, Reboussin E, Dégardin-Chicaud J, Charbonnier A, Domínguez-López A, Villette T, Denoyer A, Baudouin C, Réaux-Le Goazigo A, and Mélik Parsadaniantz S

Abstract

Photophobia may arise from various causes and frequently accompanies numerous ocular diseases. In modern highly illuminated world, complaints about greater photosensitivity to blue light increasingly appear. However, the pathophysiology of photophobia is still debated. In the present work, we investigated in vivo the role of various neural pathways potentially implicated in blue-light aversion. Moreover, we studied the light-induced neuroinflammatory processes on the ocular surface and in the trigeminal pathways. Adult male C57BL/6J mice were exposed either to blue (400-500 nm) or to yellow (530-710 nm) LED light (3 h, 6 mW/cm 2 ). Photosensitivity was measured as the time spent in dark or illuminated parts of the cage. Pharmacological treatments were applied: topical instillation of atropine, pilocarpine or oxybuprocaine, intravitreal injection of lidocaine, norepinephrine or "blocker" of the visual photoreceptor transmission, and intraperitoneal injection of a melanopsin antagonist. Clinical evaluations (ocular surface state, corneal mechanical sensitivity and tear quantity) were performed directly after exposure to light and after 3 days of recovery in standard light conditions. Trigeminal ganglia (TGs), brainstems and retinas were dissected out and conditioned for analyses. Mice demonstrated strong aversion to blue but not to yellow light. The only drug that significantly decreased the blue-light aversion was the intraperitoneally injected melanopsin antagonist. After blue-light exposure, dry-eye-related inflammatory signs were observed, notably after 3 days of recovery. In the retina, we observed the increased immunoreactivity for GFAP, ATF3, and Iba1; these data were corroborated by RT-qPCR. Moreover, retinal visual and non-visual photopigments distribution was altered. In the trigeminal pathway, we detected the increased mRNA expression of cFOS and ATF3 as well as alterations in cytokines' levels. Thus, the wavelength-dependent light aversion was mainly mediated by melanopsin-containing cells, most likely in the retina. Other potential pathways of light reception were also discussed. The phototoxic message was transmitted to the trigeminal system, inducing both inflammation at the ocular surface and stress in the retina. Further investigations of retina-TG connections are needed.

Published

2019

10. Blue light phototoxicity toward human corneal and conjunctival epithelial cells in basal and hyperosmolar conditions.

Author

Marek V, Mélik-Parsadaniantz S, Villette T, Montoya F, Baudouin C, Brignole-Baudouin F, and Denoyer A

Subjects

Antioxidants metabolism, Cell Death genetics, Cell Line, Cell Survival radiation effects, Conjunctiva radiation effects, Cornea radiation effects, Cytokines metabolism, Dry Eye Syndromes pathology, Epithelial Cells metabolism, Epithelial Cells radiation effects, Humans, Inflammation pathology, Light adverse effects, Osmolar Concentration, Reactive Oxygen Species metabolism, Conjunctiva metabolism, Cornea metabolism, Dry Eye Syndromes metabolism, Inflammation metabolism

Abstract

Aims: The ocular surface is the very first barrier between the visual system and external environment. It protects the eye from the exposure to various light sources that significantly emit in blue spectrum. However, the impact of blue light on the ocular surface has been poorly explored so far. In this study, we investigated in vitro the phototoxicity of blue light illumination in human epithelial cells of the ocular surface. We worked either in basal conditions or under hyperosmolar stress, in order to mimic dry eye disease (DED) that is the most common disease involving the ocular surface., Results: Corneal and conjunctival epithelial cells suffered the most from violet-blue light but also from longer-wave blue light. Exposure to blue wavebands significantly decreased cellular viability, impacted on cellular morphology and provoked reactive oxygen species (ROS) over-production. Conjunctival epithelial cell line had a greater photosensitivity than the corneal epithelial one. Hyperosmolar stress potentiated the blue light phototoxicity, increasing inflammation, altering mitochondrial membrane potential, and triggering the glutathione-based antioxidant system., Innovation: In human epithelial corneal and conjunctival cells of the ocular surface, we demonstrated the harmful impact of blue light on viability, redox state and inflammation processes, which was modified by hyperosmolarity., Conclusion: Blue light induced cell death and significant ROS production, and altered the expression of inflammatory genes and operation of the cellular defensive system. We established for the first time that hyperosmolar stress impacted phototoxicity, further suggesting that DED patients might be more sensitive to blue light ocular toxicity., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published

2018

11. Light action spectrum on oxidative stress and mitochondrial damage in A2E-loaded retinal pigment epithelium cells.

Author

Marie M, Bigot K, Angebault C, Barrau C, Gondouin P, Pagan D, Fouquet S, Villette T, Sahel JA, Lenaers G, and Picaud S

Subjects

Action Spectrum, Animals, Catalase metabolism, Epithelial Cells metabolism, Epithelial Cells radiation effects, Humans, Macular Degeneration genetics, Macular Degeneration metabolism, Mitochondria metabolism, Reactive Oxygen Species metabolism, Retina metabolism, Retina radiation effects, Retinal Pigment Epithelium cytology, Retinal Pigment Epithelium metabolism, Superoxide Dismutase metabolism, Swine, Light adverse effects, Mitochondria radiation effects, Oxidative Stress drug effects, Photosensitizing Agents adverse effects, Retinal Pigment Epithelium radiation effects

Abstract

Aims: Blue light is an identified risk factor for age-related macular degeneration (AMD). We investigated oxidative stress markers and mitochondrial changes in A2E-loaded retinal pigment epithelium cells under the blue-green part of the solar spectrum that reaches the retina to better understand the mechanisms underlying light-elicited toxicity., Results: Primary retinal pigment epithelium cells were loaded with a retinal photosensitizer, AE2, to mimic aging. Using a custom-made illumination device that delivers 10 nm-wide light bands, we demonstrated that A2E-loaded RPE cells generated high levels of both hydrogen peroxide (H 2 O 2 ) and superoxide anion (O 2 •- ) when exposed to blue-violet light. In addition, they exhibited perinuclear clustering of mitochondria with a decrease of both their mitochondrial membrane potential and their respiratory activities. The increase of oxidative stress resulted in increased levels of the oxidized form of glutathione and decreased superoxide dismutase (SOD) and catalase activities. Furthermore, mRNA expression levels of the main antioxidant enzymes (SOD2, catalase, and GPX1) also decreased., Conclusions: Using an innovative illumination device, we measured the precise action spectrum of the oxidative stress mechanisms on A2E-loaded retinal pigment epithelium cells. We defined 415-455 nm blue-violet light, within the solar spectrum reaching the retina, to be the spectral band that generates the highest amount of reactive oxygen species and produces the highest level of mitochondrial dysfunction, explaining its toxic effect. This study further highlights the need to filter these wavelengths from the eyes of AMD patients.

Published

2018

12. Phototoxic action spectrum on a retinal pigment epithelium model of age-related macular degeneration exposed to sunlight normalized conditions.

Author

Arnault E, Barrau C, Nanteau C, Gondouin P, Bigot K, Viénot F, Gutman E, Fontaine V, Villette T, Cohen-Tannoudji D, Sahel JA, and Picaud S

Subjects

Aging, Animals, Apoptosis, Cell Survival, Cells, Cultured, Humans, Macular Degeneration pathology, Retinal Pigment Epithelium pathology, Swine, Macular Degeneration etiology, Retinal Pigment Epithelium radiation effects, Sunlight adverse effects

Abstract

Among the identified risk factors of age-related macular degeneration, sunlight is known to induce cumulative damage to the retina. A photosensitive derivative of the visual pigment, N-retinylidene-N-retinylethanolamine (A2E), may be involved in this phototoxicity. The high energy visible light between 380 nm and 500 nm (blue light) is incriminated. Our aim was to define the most toxic wavelengths in the blue-green range on an in vitro model of the disease. Primary cultures of porcine retinal pigment epithelium cells were incubated for 6 hours with different A2E concentrations and exposed for 18 hours to 10 nm illumination bands centered from 380 to 520 nm in 10 nm increments. Light irradiances were normalized with respect to the natural sunlight reaching the retina. Six hours after light exposure, cell viability, necrosis and apoptosis were assessed using the Apotox-Glo Triplex™ assay. Retinal pigment epithelium cells incubated with A2E displayed fluorescent bodies within the cytoplasm. Their absorption and emission spectra were similar to those of A2E. Exposure to 10 nm illumination bands induced a loss in cell viability with a dose dependence upon A2E concentrations. Irrespective of A2E concentration, the loss of cell viability was maximal for wavelengths from 415 to 455 nm. Cell viability decrease was correlated to an increase in cell apoptosis indicated by caspase-3/7 activities in the same spectral range. No light-elicited necrosis was measured as compared to control cells maintained in darkness. Our results defined the precise spectrum of light retinal toxicity in physiological irradiance conditions on an in vitro model of age-related macular degeneration. Surprisingly, a narrow bandwidth in blue light generated the greatest phototoxic risk to retinal pigment epithelium cells. This phototoxic spectrum may be advantageously valued in designing selective photoprotection ophthalmic filters, without disrupting essential visual and non-visual functions of the eye.

Published

2013