Global ETD Search

71	Etude de la réponse des cellules souches épidermiques aux stress génotoxiques radiatifs / Epidermal stem cells response to radiative genotoxic stress Marie, Mélanie 19 February 2013 (has links) La peau étant le premier tissu exposé aux diverses agressions de l’environnement extérieur, les cellules qui la composent doivent disposer de mécanismes de protection vis-à-vis de ces agressions, afin d’assurer le maintien de l’homéostasie tissulaire. Les cellules souches de l’épiderme assurant le renouvellement du compartiment épithélial pendant toute la vie de l’individu, la préservation de l’intégrité de leur génome est essentielle à la fonctionnalité pérenne de la peau. Mon doctorat avait pour objectif d’explorer les mécanismes mis en œuvre par les cellules souches de l’épiderme interfolliculaire afin de se protéger de deux stress génotoxiques radiatifs, à savoir : les rayonnements gamma et les rayonnements ultraviolets B (UVB). Durant mon doctorat, j’ai tout d’abord participé à la démonstration des mécanismes de protection mis en œuvre par les cellules souches des kératinocytes après irradiation ionisante. En effet, il a été montré que ces cellules sont capables de réparer très rapidement l’ensemble des dommages de l’ADN radio-induits, et que cette réparation était activée par le facteur de croissance FGF2 (Fibroblast Growth Factor 2). Afin de savoir si ce mécanisme de protection était aussi opérant dans les cellules souches de carcinome cutané, nous l’avons recherché dans la sous-population de cellules souches qui peut être isolée d’une lignée de carcinome cutané humain. Comme dans le cas des cellules souches normales, nous avons montré que les cellules souches de cancer présentent une réparation très rapide des dommages de l’ADN radio-induits. De plus, le facteur de croissance FGF2 participe à cette réparation, notamment par la présence d’isoformes de ce facteur dans le noyau cellulaire. Le second projet de mon doctorat avait pour objectif l’étude de la réponse des cellules souches et des progéniteurs de l’épiderme humain aux rayonnements UVB. Une fois mises en place les conditions de tri en cytométrie de flux et d’irradiation par les UVB, la toxicité de ces rayonnements a été évaluée dans un modèle cellulaire primaire. Nous avons caractérisé les effets des photons UVB sur la viabilité et la prolifération cellulaire et étudié la réparation des dommages de l’ADN. Cette étude nous a permis de mettre en évidence des réponses aux UVB différentes entre les cellules souches et leur descendance immédiate, les kératinocytes progéniteurs, notamment au niveau de l’activité de réparation des dommages de l’ADN. Par ailleurs, une étude du transcriptome des cellules irradiées a été réalisée, qui permet d’analyser les mécanismes globaux communs et spécifiques de réponse au stress dans les deux populations. L’ensemble des données obtenues nous permet de proposer plusieurs mécanismes de protection, communs et spécifiques, mis en œuvre par les cellules souches de l’épiderme en réponse aux stress radiatifs UVB et gamma. / Human skin is the first organ exposed to various environmental stresses, which requires the development by skin stem cells of specific mechanisms to protect themselves and to ensure tissue homeostasis. As stem cells are responsible for the maintenance of epidermis during individual lifetime, the preservation of genomic integrity in these cells is essential. My PhD aimed at exploring the mechanisms set up by epidermal stem cells in order to protect themselves from two genotoxic stresses, ionizing radiation ( Gamma Rays) and ultraviolet radiation (UVB). To begin my PhD, I have taken part of the demonstration of protective mechanisms used by keratinocyte stem cells after ionizing radiation. It has been shown that these cells are able to rapidly repair most types of radiation-induced DNA damage. Furthermore, we demonstrated that this repair is activated by the fibroblast growth factor 2 (FGF2). In order to know if this protective mechanism is also operating in cutaneous carcinoma stem cells, we investigated the response to gamma Rays of carcinoma stem cells isolated from a human carcinoma cell line. As in normal keratinocyte stem cells, we demonstrated that cancer stem cells could rapidly repair radio-induced DNA damage. Furthermore, fibroblast growth factor 2 also mediates this repair, notably thanks to its nuclear isoforms. The second project of my PhD was to study human epidermal stem cells and progenitors responses to UVB radiation. Once cytometry and irradiation conditions were set up, the toxicity of UVB radiation has been evaluate in the primary cell model. We then characterized UVB photons effects on cell viability, proliferation and repair of DNA damage. This study allowed us to bring out that responses of stem cells and their progeny to UVB are different, notably at the level of part of their repair activity of DNA damage. Moreover, progenitors and stem cells transcriptomic responses after UVB irradiation have been study in order to analyze the global mechanisms of stress response in the two cell populations. Taken together, data obtained during my PhD allowed us to show that stem cells respond differently than keratinocyte progenitors to radiation stress, and that they developed both intrinsic and radiation-induced strategies allowing a better protection. When comparing gamma Rays and UVB, we found that, although their toxic effects on skin share many similarities, the mechanisms set up by human epidermal stem cells to protect themselves vary according to the type of radiation stress. Cellules souches Peau Stress génotoxique Épiderme humain Stem cells Skin Genotoxic stress Human epidermis
72	Transdermal delivery of 5-Fluorouracil with PheroidTM technology / C.P. van Dyk Van Dyk, Christina Petronella January 2008 (has links) Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2008. 5-Fluorouracil Franz diffusion cell Heat separated epidermis Skin penetration Transdermal Drug delivery system PheroidTM
73	Retinoic Acid Metabolism Blocking Agents and the Skin : In vivo and in vitro Studies of the Effects on Normal and Diseased Human Epidermis Pavez Loriè, Elizabeth January 2008 (has links) Retinoic Acid Metabolism Blocking Agents (RAMBAs) increase the endogenous levels of all-trans retinoic acid (RA) by inhibiting CYP26 enzymes. Thus they are believed to mimic the effects of retinoid treatment. Their mechanism of action and effects on vitamin A metabolism in keratinocytes are however uncertain. To explore this and the function of CYP26 in human skin was the main purpose of the project. The effects of two RAMBAs (talarozole and liarozole) on the expression of retinoid biomarkers in epidermis were studied in vivo and in vitro. Normal human skin (n=16) exposed to topical talarozole for 9 days showed similar response as previously reported for topical RA, even though no skin inflammation occurred. Lamellar ichthyosis patients (n=11) treated systemically with liarozole showed variable clinical improvement after 4 weeks with only mild effects on the retinoid biomarkers and the expression did not always correlate at the protein and mRNA levels. In these studies the proinflammatory transcripts IL-1α and TNFα were down-regulated by RAMBAs. In vitro, using an organotypic epidermis model we first studied how the RA metabolism was affected by adding RA and/or RAMBAs. We next examined the effects of the same agents on the expression of vitamin A metabolising enzymes in monolayer cultures of proliferating and differentiating keratinocytes. The results show among other things that CYP26 A1 and B1 are both involved in the catabolism of RA, and that talarozole potently increases the level of endogenous RA, primarily by inhibiting CYP26B1. However the drug´s biological effects cannot be solely attributed to increased RA levels. In conclusion, RAMBAs are promising new drugs for treatment of skin disorders, but further studies on their mechanism of action are needed. CYP CYP26 retinoids vitamin A RAMBA metabolism keratinocyte epidermis retinoid regulated genes Dermatology and venerology Dermatologi och venerologi
74	Kallikrein-related peptidases in human epidermis : studies on activity, regulation, and function Stefansson, Kristina January 2008 (has links) Introduction. The outermost layer of the epidermis, the stratum corneum (SC), plays a fundamental role in our defense against microorganisms, chemicals, and dehydration. The SC is composed of tightly packed keratinized skin cells, corneocytes. For a functioning skin it is essential that corneocytes are constantly shed (desquamated). Kallikrein-related peptidase (KLK) 5 and KLK7 may be important in the desquamation process through degradation of desmosomal proteins. Severe hereditary diseases, where inhibition of KLK5 and/or KLK7 is missing, points to the importance of regulation of protease activity. KLKs may be regulated in various ways: tissue expression, activation of proforms, specific inhibitors, and physico-chemical properties like pH. Besides their involvement in desquamation, KLKs may also be important in immune defense and inflammation by processing of mediators and via activation of proteinase-activated receptors (PARs). Aims. 1. To identify and characterize previously unknown proteases in the SC. 2. To further characterize KLK5 and KLK7 with special focus on activation mechanisms. 3. To identify new inhibitors of KLKs in human SC. 4. To further characterize KLKs regarding effects of various inhibitors and substrates. 5. To study possible functions of KLKs in inflammation, in particular via activation of PAR-2. Methods. Plantar SC was used as a source for purification of proteins. Recombinant proteins were produced in different expression systems (insect cells, yeast cells, and bacteria). Different activity assays and kinetic studies were performed. Tissue expression was studied by immunohistochemistry, immunoblot and PCR. PAR-2 activation was studied by measurement of intracellular [Ca2+] and immunofluorescense in KNRK-PAR2 cells. Results. Active KLK14 was purified from extracts of plantar SC. KLK14 showed a superior catalytic efficiency as compared to KLK5 when measuring trypsin-like activity. This indicated that KLK14, despite being present in low amounts in skin, may have great relevance for skin physiology. Among enzymes tested only KLK5 showed autocatalytic activity and is so far the only enzyme found in SC that can activate proKLK7. KLK5 could also activate proKLK14. This together with studies of pH dependence on activation placed KLK5 as a possible key activating enzyme in a proposed proteolytic cascade in the SC. In plantar SC extracts we have also identified the novel Kazal-type serine protease inhibitor 9 (SPINK9). Our results indicate that SPINK9 is preferentially expressed in palmo-plantar skin and specific for KLK5. Differences found regarding substrate specificity and inhibition profile can be useful in evaluating the contribution of individual KLKs to the proteolytic activity in crude SC extracts. One interesting finding was that KLK8, present at high protein levels in the epidermis, could not be inhibited by any protease inhibitor found in the extracts. PAR-2 activation studies showed that KLK5 and 14 but neither KLK7 nor 8 can activate PAR-2. Immunohistochemistry preferentially detected KLK14 in intraepidermal parts of the sweat ducts and in dermal sweat glands but we could also show coexpression of KLK14 and PAR-2 in the SC and stratum granulosum of the epidermis in inflammatory skin disorders. To summarize, KLK involvement in desquamation may be dependent on a proteolytic activation cascade regulated by an intrinsic pH gradient and specific inhibitors present in SC. Another possible function of KLKs is as mediators of inflammation through activation of PAR-2. desquamation epidermis stratum corneum kallikrein-related peptidase KLK serine protease inhibitors Dermatology and venerology Dermatologi och venerologi
75	Chemical Composition of Soybean Root Epidermal Cell Walls Fang, Xingxiao January 2006 (has links) The root epidermis, being the outermost cell layer of the organ, is in contact with the soil environment. The position of the epidermis determines its important roles, such as taking up water and ions from the surrounding soil, and defending against harmful microorganisms. What is the chemical composition of the walls in this layer? The chemical nature of the soybean epidermal wall modifying substance was investigated in this study with the use of histochemical tests coupled with electron microscopy, and chemical depolymerizations in combination with chromatography. Soybean (<em>Glycine max</em>) was used as a test species in the present studay. Results of histochemical and electron microscopical studies indicated that the epidermal walls are modified with suberin. The suberized epidermal walls were permeable to apoplastic tracers, differing from those of cells with suberized Casparian bands, possibly due to the spatial distribution or chemical components of the suberin. Suberin may occur in a diffuse form linked with other wall components in the epidermis. What is the chemical nature of this modification, and does it play a role in pathogen resistance? The root epidermal wall compositions of two soybean cultivars were compared; one (cv. Conrad) is resistant to <em>Phytophthora sojae</em> and the other (cv. OX 760-6) is susceptible to this root-rot oomycete. Their epidermal walls were isolated enzymatically and subjected to two different degradation methods, i. e. BF<sub>3</sub>-MeOH transesterification and nitrobenzene oxidation. The compositions of depolymerisates of the cell walls determined by GC-MS indicated four dominant suberin monomers varying in chain length from C16 to C24. In all epidermal cell walls, ω-hydroxycarboxylic acids were more abundant than diacids, carboxylic acids and alcohols. Two of the monomers detected (hydroxycarboxylic acid and a,ω-dicarboxylic acid) are known to be characteristic suberin markers. The quantitative chemical compositions significantly differed in the epidermal cell walls of the two soybean varieties. Walls of the resistant cultivar (Conrad) had a greater quantity of both the aliphatic and aromatic components of the polymer than the susceptible cultivar (OX760-6), providing evidence to support the hypothesis that preformed suberin plays a role in plant defense. Biology root epidermis chemical composition soybean suberin pathogen resistance Phytophthora sojae suberin monomers
76	Transdermal delivery of 5-Fluorouracil with PheroidTM technology / C.P. van Dyk Van Dyk, Christina Petronella January 2008 (has links) 5-Fluorouracil (5FU) is a pyrimidine analogue, indicated for the therapy of proliferative skin diseases such as actinic keratosis (AK), superficial basal cell carcinoma and psoriasis. It has also been used for the treatment of solid tumours like colorectal, breast and liver carcinomas for nearly 40 years. Although 5FU has always been administered parenterally and orally, metabolism is rapid and absorption is erratic. Several severe side-effects are also commonly associated with 5FU therapy, including myelosuppression, hand-foot syndrome and gastrointestinal effects. Seeing that 5FU is an important part of the treatment of several malignant and pre-malignant disorders, it would be advantageous to find a delivery route and delivery system that negate absorption and metabolic variation and decrease side-effects. The transdermal route provides a promising alternative to the above-mentioned conventional delivery routes, solving most of the problems associated with parenteral and oral administration. That being said, the formidable barrier situated in the skin is not easily breached. The stratum corneum, the outermost skin layer, is mostly lipophilic in nature, preventing hydrophilic molecules such as 5FU from entering. 5FU-containing creams and lotions are currently commercially available, but absorption is still very limited. The transdermal absorption from these formulations has been compared to that obtained with the use of new transdermal delivery vehicles, with the newer formulations proving to be promising. It was decided to entrap 5FU in a novel therapeutic system, in the form of the Pheroid™ system, to increase its transdermal penetration. Pheroid™ vesicles are stable spherical structures in a unique, emulsion-like formulation, and fall in the submicron range. The main components of the Pheroid™ system are the ethyl esters of the essential fatty acids linoleic acid and linolenic acid, as well as the cys-form of oleic acid, and water. The formulation is saturated with nitrous oxide (N20). Although Pheroid™ vesicles may resemble other lipid-based vehicles, such as liposomes and micro-emulsions, they are unique in the sense that they have inherent therapeutic qualities as well. The Pheroid™ formulation can be specifically manipulated to yield different types of vesicles, ensuring a fast transport rate, high entrapment efficiency, rapid delivery and stability of the delivery system for a specific drug. In this study, 5FU was entrapped in the Pheroid™ formulation. Transdermal permeation studies were then performed to evaluate the influence of this delivery system on the transdermal flux of 5FU. Vertical Franz diffusion cells were utilised to determine the transdermal penetration of 5FU. Only Caucasian female abdominal skin was used to minimise physiological variables. Diffusion studies were done over 12 hour periods, with the entire receptor phase being withdrawn at predetermined intervals. Samples were analysed using high performance liquid chromatography (HPLC), after which the cumulative concentration of active was plotted against time. The linear portion of this graph represents the flux of 5FU through the skin. It was found that there were differences in the results between formulations containing 5FU in a phosphate buffer solution (PBS)-based Pheroid™ and water-based Pheroid™, though the difference was not statistically significant. The 0.5 % 5FU in water-based Pheroid™ resulted in a significantly bigger yield than the control (1 % 5FU in water) as well as a significant difference to the 1 % 5FU in PBS-based Pheroid™ formulation. In general the water-based Pheroid™ formulations had greater average cumulative concentrations, yields and fluxes than the other formulations. The fluxes obtained with the water-based Pheroid™ formulations also correlated well with a previous study done by Kilian (2004). Thus it can be concluded that the Pheroid™ therapeutic delivery system enhances the transdermal penetration of 5FU. Water-based Pheroid™ formulations proved to be more effective than PBS-based Pheroid™ formulations. It can also be concluded that a 0.5 % 5FU in water-based Pheroid™ formulation can be used instead of a 1 % formulation, because there were no statistically significant differences between the two formulations. This would be advantageous - patient compliance can be enhanced because of a more tolerable formulation with fewer side effects, while manufacturing cost is lowered by using a lower concentration of active. It is recommended that some aspects of the study be investigated further to optimise the transdermal delivery of 5FU using the Pheroid™ therapeutic system. These aspects include optimising the composition of the Pheroid formulation, investigating the entrapment process of 5FU within Pheroid™ spheres, the influence of PBS and water as basis of the Pheroid™ formulation and the amount of 5FU remaining in the epidermis after the 12 hour period of the diffusion study. Keywords: 5-Fluorouracil, Franz diffusion cell, Heat separated epidermis, Skin penetration, Transdermal, Drug delivery system, Pheroid™ / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2008. 5-Fluorouracil Franz diffusion cell Heat separated epidermis Skin penetration Transdermal Drug delivery system PheroidTM
77	Regulation of Asymmetric Cell Divisions in the Developing Epidermis Poulson, Nicholas January 2012 (has links) <p>During development, oriented cell divisions are crucial for correctly organizing and shaping a tissue. Mitotic spindle orientation can be coupled with cell fate decisions to provide cellular diversity through asymmetric cell divisions (ACDs), in which the division of a progenitor cell results in two daughters with different cell fates. Proper tissue morphogenesis relies on the coupling of these two phenomena being highly regulated. The development of the mouse epidermis provides a powerful system in which to study the many levels that regulate ACDs. Within the basal layer of the epidermis, both symmetric and asymmetric cell divisions occur. While symmetric divisions allow for an increase in surface area and progenitor cell number, asymmetric divisions drive the stratification of the epidermis, directly contributing additional cell layers (Lechler and Fuchs 2005; Poulson and Lechler 2010; Williams, Beronja et al. 2011). </p><p>Utilizing genetic lineage tracing to label individual basal cells I show that individual basal cells can undergo both symmetric and asymmetric divisions. Therefore, the balance of symmetric:asymmetric divisions is provided by the sum of individual cells' choices. In addition, I define two control points for determining a cell's mode of division. First is the expression of the mInscuteable gene, which is sufficient to drive ACDs. However, there is robust control of division orientation as excessive ACDs are prevented by a change in the localization of NuMA, an effector of spindle orientation. Finally, I show that p63, a transcriptional regulator of stratification, does not control either of these processes, rather it controls ACD indirectly by promoting cell polarity. </p><p>Given the robust control on NuMA localization to prevent excess ACDs, I sought to determine how targeting of NuMA to the cortex is regulated. First, I determined which regions within the protein were necessary and sufficient for cortical localization. NuMA is a large coiled- coil protein that binds many factors important for ACDs, which include but are not limited to: microtubules, 4.1, and LGN. Interestingly, while the LGN binding domain was necessary, it was not sufficient for proper NuMA localization at the cortex. However, a fragment of NuMA containing both the 4.1 and LGN binding domains was able to localize to the cortex. Additionally, the NuMA-binding domain of 4.1 was able to specifically disrupt NuMA localization at the cortex. These data suggested an important role for a NuMA-4.1 interaction at the cortex. While the 4.1 binding domain was not necessary for the cortical localization of NuMA, it was important for the overall stability of NuMA at the cortex. I hypothesize that 4.1 acts to anchor/stabilize NuMA at the cortex to provide resistance against pulling forces on the mitotic spindle to ensure proper spindle orientation.</p><p>Finally, to determine if post-translational modifications of NuMA could regulate its localization I tested the importance of a conserved Cdk-1 phosphorylation site. Interestingly, a non-phosphorylatable form of NuMA localized predominately to the cortex while the phosphomimetic protein localized strongly to spindle poles. In agreement with these data, use of a CDK-1 inhibitor was able to enhance the cortical localization of NuMA. Unexpectedly, the non-phosphorylatable form of NuMA did not require LGN to localize to the cortex. Additionally, restoration of cortical localization of the phosphomimetic form of NuMA was accomplished by the overexpression of either LGN or 4.1. Thus, phosphorylation of NuMA may alter its overall affinity for the cortex. </p><p>Overall, my studies highlight two important regulatory mechanisms controlling asymmetric cell division in the epidermis. Additionally, I show a novel role for the interaction between NuMA and 4.1 in providing stability at the cortex. This will ultimately provide a framework for analysis of how external cues control the important choice between asymmetric and symmetric cell divisions.</p> / Dissertation Cellular biology Developmental biology Molecular biology Asymmetric Cell Division Epidermis Inscuteable NuMA
78	Transdermal delivery of 5-Fluorouracil with PheroidTM technology / C.P. van Dyk Van Dyk, Christina Petronella January 2008 (has links) 5-Fluorouracil (5FU) is a pyrimidine analogue, indicated for the therapy of proliferative skin diseases such as actinic keratosis (AK), superficial basal cell carcinoma and psoriasis. It has also been used for the treatment of solid tumours like colorectal, breast and liver carcinomas for nearly 40 years. Although 5FU has always been administered parenterally and orally, metabolism is rapid and absorption is erratic. Several severe side-effects are also commonly associated with 5FU therapy, including myelosuppression, hand-foot syndrome and gastrointestinal effects. Seeing that 5FU is an important part of the treatment of several malignant and pre-malignant disorders, it would be advantageous to find a delivery route and delivery system that negate absorption and metabolic variation and decrease side-effects. The transdermal route provides a promising alternative to the above-mentioned conventional delivery routes, solving most of the problems associated with parenteral and oral administration. That being said, the formidable barrier situated in the skin is not easily breached. The stratum corneum, the outermost skin layer, is mostly lipophilic in nature, preventing hydrophilic molecules such as 5FU from entering. 5FU-containing creams and lotions are currently commercially available, but absorption is still very limited. The transdermal absorption from these formulations has been compared to that obtained with the use of new transdermal delivery vehicles, with the newer formulations proving to be promising. It was decided to entrap 5FU in a novel therapeutic system, in the form of the Pheroid™ system, to increase its transdermal penetration. Pheroid™ vesicles are stable spherical structures in a unique, emulsion-like formulation, and fall in the submicron range. The main components of the Pheroid™ system are the ethyl esters of the essential fatty acids linoleic acid and linolenic acid, as well as the cys-form of oleic acid, and water. The formulation is saturated with nitrous oxide (N20). Although Pheroid™ vesicles may resemble other lipid-based vehicles, such as liposomes and micro-emulsions, they are unique in the sense that they have inherent therapeutic qualities as well. The Pheroid™ formulation can be specifically manipulated to yield different types of vesicles, ensuring a fast transport rate, high entrapment efficiency, rapid delivery and stability of the delivery system for a specific drug. In this study, 5FU was entrapped in the Pheroid™ formulation. Transdermal permeation studies were then performed to evaluate the influence of this delivery system on the transdermal flux of 5FU. Vertical Franz diffusion cells were utilised to determine the transdermal penetration of 5FU. Only Caucasian female abdominal skin was used to minimise physiological variables. Diffusion studies were done over 12 hour periods, with the entire receptor phase being withdrawn at predetermined intervals. Samples were analysed using high performance liquid chromatography (HPLC), after which the cumulative concentration of active was plotted against time. The linear portion of this graph represents the flux of 5FU through the skin. It was found that there were differences in the results between formulations containing 5FU in a phosphate buffer solution (PBS)-based Pheroid™ and water-based Pheroid™, though the difference was not statistically significant. The 0.5 % 5FU in water-based Pheroid™ resulted in a significantly bigger yield than the control (1 % 5FU in water) as well as a significant difference to the 1 % 5FU in PBS-based Pheroid™ formulation. In general the water-based Pheroid™ formulations had greater average cumulative concentrations, yields and fluxes than the other formulations. The fluxes obtained with the water-based Pheroid™ formulations also correlated well with a previous study done by Kilian (2004). Thus it can be concluded that the Pheroid™ therapeutic delivery system enhances the transdermal penetration of 5FU. Water-based Pheroid™ formulations proved to be more effective than PBS-based Pheroid™ formulations. It can also be concluded that a 0.5 % 5FU in water-based Pheroid™ formulation can be used instead of a 1 % formulation, because there were no statistically significant differences between the two formulations. This would be advantageous - patient compliance can be enhanced because of a more tolerable formulation with fewer side effects, while manufacturing cost is lowered by using a lower concentration of active. It is recommended that some aspects of the study be investigated further to optimise the transdermal delivery of 5FU using the Pheroid™ therapeutic system. These aspects include optimising the composition of the Pheroid formulation, investigating the entrapment process of 5FU within Pheroid™ spheres, the influence of PBS and water as basis of the Pheroid™ formulation and the amount of 5FU remaining in the epidermis after the 12 hour period of the diffusion study. Keywords: 5-Fluorouracil, Franz diffusion cell, Heat separated epidermis, Skin penetration, Transdermal, Drug delivery system, Pheroid™ / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2008. 5-Fluorouracil Franz diffusion cell Heat separated epidermis Skin penetration Transdermal Drug delivery system PheroidTM
79	Studies on the mechanism of staphylococcal conjugation Von David, William J. January 1998 (has links) Thesis (Ph. D.)--University of Missouri--Columbia, 1998. / Typescript. Vita. Includes bibliographical references (leaves: [89]-98). Also available on the Internet.
80	Estudo de amostras de Staphylococcus coagulase-negativa quanto a formação de biofilme Bernardi, Adilson César Abreu [UNESP] 13 December 2005 (has links) (PDF) Made available in DSpace on 2014-06-11T19:32:55Z (GMT). No. of bitstreams: 0 Previous issue date: 2005-12-13Bitstream added on 2014-06-13T19:22:47Z : No. of bitstreams: 1 bernardi_aca_dr_arafcf.pdf: 1525508 bytes, checksum: c65f0bdce77e95dac615f5ee33dd6287 (MD5) / Universidade Estadual Paulista (UNESP) / Os Staphylococcus coagulase-negativa, particularmente, os Staphylococcus epidermidis são a causa mais freqüente de infecções relacionadas ao cateter por sua habilidade em aderir a uma superfície e entre si (aderência intercelular) formando biofilme em multicamadas sobre superfícies de polímeros. O objetivo do presente estudo foi avaliar cepas hospitalares de Staphylococcus coagulasenegativa isoladas de cateteres intravenosos, quanto à resistência a oxacilina, produção de slime, aderência ao poliestireno, habilidade de formar biofilme sobre superfícies abióticas (cateter esterilizado) e a presença de genes icaAD. Na presente pesquisa, a presença de icaA e icaD foi determinada pelo método PCR, em uma coleção de 27 amostras Staphylococcus coagulase-negativa (10 Staphylococcus epidermidis, 4 S. haemolyticus, 2 S. hominis, 2 S. lugdunensis, 1 S. saprophyticus, 1 S. schleiferi, 2 S. xylosus e 4 S. warneri). Os genes icaAD foram detectados em dez cepas S. epidermidis... / Coagulase-negative Staphylococcus, particularly, Staphylococcus epidermidis are frequent cause of infections associated with catheters and is attributed to the attachment ability on a surface and each other (intercellular adhesion) forming a multilayered biofilm on polymeric surfaces. The objective of the present study was to evaluate coagulase-negative Staphylococcus strains isolated from intravenous catheters by oxacillin resistance, slime production (qualitative method) and spectrophotometric assay (quantitative method), ability to form biofilm on abiotic surfaces (steriled catheter) and the presence of icaAD genes. In the present study icaA and icaD were determined by PCR method, in a collection of 27 coagulasenegative Staphylococcus (10 Staphylococcus epidermidis, 4 S. haemolyticus, 2 S. hominis, 2 S. lugdunensis, 1 S. saprophyticus, 1 S. schleiferi, 2 S. xylosus and 4 S. warneri). The icaA genes were detected in nine S. epidermidis and icaD in ten. The slime-producing ability was determined by culture on Congo red agar plates in which slime-producing strains formed black colonies in 10 S. epidermidis, 4 S.haemolyticus, 4 S. warneri, 2 S. xylosus and 1 S. chromogenes, while nonslimeformingones develop red colonies. The quantitative assay of coagulase-negative Staphylococcus was observed in 19 strains, including: 10 S. epidermidis, 3 S.haemolyticus, 3 S. warneri, 2 S. xylosus, 1 S. chromogenes. The ability of coagulasenegative Staphylococcus to form biofilm embedded in an amorphous substance wasobserved by scanning electronic microscope on abiotic surface in 10 S. epidermidis,3 S. haemolyticus, 2 S. hominis, 2 S. lugdunensis, 1 S. saprophyticus, 1 S. schleiferi,2 S. xylosus and 3 S. warneri. The oxacillin resistance was observed in 9 strains S.epidermidis, 3 S. haemolyticus, 3 S. warneri, 1 S. xylosus and 1 S. chromogenes. All strains of staphylococci were susceptible... (Complete abstract, click eletronic address below) Microbiologia médica Staphyloccocus epidermis Slime Operon ica Fatores de virulência Virulence factors

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