Staphylococcus epidermidis lipase : biochemical and molecular genetic analysis

Farrell, Angela Margaret

January 1989

No description available.

579

Microbiology/human skin][Skin microflora

Traditional use of Trichilia emetica for treatment of post-inflammatory hyperpigmentation.

Komane, Baatile Mmammoti.

January 2010

Thesis (MTech. degree in Pharmaceutical Sciences)--Tshwane University of Technology, 2010. / Aims to assess the efficacy and adverse effects of Trichilia emetica in reducing post-inflammatory hyperpigmentation on black skin.

Pharmacognosy.

Ethnopharmacology.

Phytochemicals.

Trichilia.

Human skin color.

An investigation of skin color as a salient variable in interpersonal preferences in dyadic and group social situations among elementary school children, black and white, boys and girls

Dirlam, Karen S.

January 1900

Thesis (Ph. D.)--University of Wisconsin--Madison, 1973. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliography.

Electroporation and ultradeformable liposomes; human skin barrier repair by phospholipid.

Essa, Ebtessam A., Bonner, Michael C., Barry, Brian W.

January 2003

No / This work investigated the effect of electroporation on human epidermal penetration of a model neutral lipophilic compound (estradiol) from saturated aqueous solution and when encapsulated in ultradeformable liposomes. Total amount penetrated and skin deposition were compared with values obtained from passive diffusion. The effect of electrical pulsing on liposome size was investigated. The action of phosphatidylcholine on skin that was structurally altered by such pulses was determined. Electroporation did not affect liposome size. Skin pulsing considerably increased estradiol penetration and skin deposition from solution, relative to passive delivery, with subsequent partial recovery of skin resistance to molecular penetration. Surprisingly, with liposomes, electroporation did not markedly affect estradiol skin penetration. Importantly, liposomal phosphatidylcholine applied during or after pulsing accelerated skin barrier repair, i.e. provided an anti-enhancer or retardant effect.

Electroporation

Liposomes

Phospholipid

Human skin

Estradiol

Q10-triggered facial vitiligo.

Schallreuter, Karin U.

17 August 2013

no / Background Generation and accumulation of reactive oxygen/nitrogen species in the epidermis of patients with vitiligo has been widely documented. Moreover, semiquinone radical-mediated sensitivity has been shown in blood lymphocytes of these patients. Objectives To determine the possible mechanism behind Q10-induced facial vitiligo. Methods This was a clinical assessment supported by in vivo Fourier transform–Raman spectroscopy and repigmentation. Results Topical Q10 application generated hydrogen peroxide (H2O2) leading in turn to facial vitiligo in susceptible individuals. Proof of the basic result stemmed from reduction of epidermal H2O2 by using narrowband ultraviolet B-activated propseudocatalase PC-KUS in association with cessation of depigmentation and repigmentation of the lost skin colour. Conclusions Over-the-counter availability of Q10-containing topical formulations can be harmful to individuals susceptible to vitiligo.

Echoes of racism an exploration into skin color bias within the African American community : a project based upon an independent investigation /

Daniels, Claretta D.

January 2009

Thesis (M.S.W.)--Smith College School for Social Work, Northampton, Mass., 2009. / Includes bibliographical references (p. 137-146).

Studies of the physical and chemical properties of 1,4 dioxane and their relevance to adsorption and transdermal absorption

Mahdi, Ali Jafar

January 1900

Doctor of Philosophy / Department of Diagnostic Medicine/Pathobiology / Deon van der Merwe / 1,4-Dioxane is a potentially carcinogenic solvent. It is a problematic groundwater contaminant because of its unique physical-chemical properties. It is found in a wide range of consumer products as a by-product contaminant. This research aimed to investigate contaminant properties and behavior of dioxane in the environment and also in the human body. The dioxane ability to decontamination by adsorption processes was evaluated with four adsorbents. The adsorption efficiencies of activated carbon (AC), metal oxide nanomaterials (TiO[subscript]2 and MgO), and diatomaceous earth (DE) were assessed in aqueous and vapor phases using infrared spectroscopy. AC showed the highest adsorptive capacity for dioxane at equilibrium in both phases. The rate and extent of dermal absorption are important in the analysis of risk from dermal exposure to dioxane. For this purpose, a new flow through diffusion system (FTDS) was developed by modifying a Bronaugh flow through diffusion cell with flow capacity in both the donor and receptor compartments and using attenuated total reflection Fourier transform infrared spectroscopy (ATR-FTIR) as the analytical technique. FTDS can provide ‘real time’ quantitative high-density permeation data over time and is characterized by the simplicity of its use and the low cost of test samples. The in vitro dermal absorption study of dioxane across human skin showed that the absorption parameters of dioxane were 1.16 ± 0.22 hr, 5.7 X 10[superscript]-4 ± (0.62) cm/hr, 0.286 ± 0.035 mg/cm2/hr, 4.8 X 10-5 (± 0.32) cm[superscript]2/hr, and 1.99 ± 0.086 mg for lag time, permeability, steady-state flux, diffusivity, and total amount absorbed over 8 hr, respectively. The study of the effect of the surfactant sodium lauryl sulphate and solvent systems water, ethanol, propylene glycol, and ethyl acetate on permeation profiles revealed that these solvents and surfactants increased the permeation of dioxane significantly. The FT-IR spectra of stratum corneum treated with solvents showed that there was broadening of the CH[subscript]2 asymmetric stretching vibration of the CH[subscript]2 peak near 2920 cm[superscript]-1 only in samples treated with ethanol. The lipid extract precipitates were detected and were mostly composed of the stratum corneum lipid part.

1,4 Dioxane

Adsorption

Dermal absorption

Human skin

Water

Toxicology (0383)

Human Skin Modelling and Rendering

Poirier, Guillaume

January 2004

Creating realistic-looking skin is one of the holy grails of computer graphics and is still an active area of research. The problem is challenging due to the inherent complexity of skin and its variations, not only across individuals but also spatially and temporally among one. Skin appearance and reflectance vary spatially in one individual depending on its location on the human body, but also vary temporally with the aging process and the body state. Emotions, health, physical activity, and cosmetics for example can all affect the appearance of skin. The spatially varying reflectance of skin is due to many parameters, such as skin micro- and meso-geometry, thickness, oiliness, and pigmentation. It is therefore a daunting task to derive a model that will include all these parameters to produce realistic-looking skin. The problem is also compounded by the fact that we are very well accustomed to the appearance of skin and especially sensitive to facial appearances and expressions. Skin modelling and rendering is crucial for many applications such as games, virtual reality, films, and the beauty industry, to name a few. Realistic-looking skin improves the believability and realism of applications. The complexity of skin makes the topic of skin modelling and rendering for computer graphics a very difficult, but highly stimulating one. Skin deformations and biomechanics is a vast topic that we will not address in this dissertation. We rather focus our attention on skin optics and present a simple model for the reflectance of human skin along with a system to support skin modelling and rendering.

Computer Science

Human skin

skin optics

skin rendering

skin reflectance

Organotypic human skin disease models for the assessment of novel therapeutic approaches

Fell, Benjamin

January 2017

Comprehensive in vitro modelling of inflammatory human skin conditions is an essential first step in the development and assessment of potential therapeutic approaches. Mouse models or monolayer keratinocyte cultures come with distinct limitations which might be complimented or overcome by the use of human-specific organotypic 3D culture models. Over the course of this thesis, an organotypic culture system, based on patientderived immortalised keratinocyte cell lines on a dermal equivalent collagen 1 gel, was established and used to recapitulate phenotypical features for two hereditary skin diseases, Harlequin ichthyosis and Tylosis with oesophageal cancer. Small molecular compounds, supplied via the medium, or RNA interference were used to modulate disease-specific changes in histology and marker expression of the skin equivalent. Since hyperproliferative skin conditions can be associated with an aberrant wound healing phenotype, the organotypic system was manipulated to obtain a basic in vitro wound healing model. This model displays typical features of re-epithelialisation over time (both normal and disease-specific) which can further be manipulated via shRNAmediated knockdown or the exogenous supply of compounds. In parallel, a non-disease model was used to assess the topical application of novel nanopolymeric drug delivery systems in regard to their ability to penetrate across the permeability barrier. Penetrance profiles for the organotypic model (in dependence of co-application with chemical enhancers) showed a similar pattern as for topical applications performed in parallel on explant skin. In conclusion, a highly adaptable human organotypic keratinocyte culture model was developed and used to recapitulate (and manipulate) skin disease phenotypes and epidermal wound healing in vitro, as well as perform first essential assessments of novel drug delivery systems.

Human Skin Modelling and Rendering

Poirier, Guillaume

January 2004

Creating realistic-looking skin is one of the holy grails of computer graphics and is still an active area of research. The problem is challenging due to the inherent complexity of skin and its variations, not only across individuals but also spatially and temporally among one. Skin appearance and reflectance vary spatially in one individual depending on its location on the human body, but also vary temporally with the aging process and the body state. Emotions, health, physical activity, and cosmetics for example can all affect the appearance of skin. The spatially varying reflectance of skin is due to many parameters, such as skin micro- and meso-geometry, thickness, oiliness, and pigmentation. It is therefore a daunting task to derive a model that will include all these parameters to produce realistic-looking skin. The problem is also compounded by the fact that we are very well accustomed to the appearance of skin and especially sensitive to facial appearances and expressions. Skin modelling and rendering is crucial for many applications such as games, virtual reality, films, and the beauty industry, to name a few. Realistic-looking skin improves the believability and realism of applications. The complexity of skin makes the topic of skin modelling and rendering for computer graphics a very difficult, but highly stimulating one. Skin deformations and biomechanics is a vast topic that we will not address in this dissertation. We rather focus our attention on skin optics and present a simple model for the reflectance of human skin along with a system to support skin modelling and rendering.

Computer Science

Human skin

skin optics

skin rendering

skin reflectance