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Étude du lien entre maladie alcoolique du foie, microbiote intestinal et acides biliaires : rôles spécifiques de la pectine et du récepteur aux acides biliaires TGR5 / Study of the link between alcoholic liver disease, intestinal microbiota and bile acids : key-role of pectin and of the bile acids receptor TGR5Spatz, Madeleine 15 October 2018 (has links)
La maladie alcoolique du foie (MAF) regroupe l’ensemble des lésions qui apparaissent suite à une consommation excessive et chronique d’alcool. A consommation d’alcool égale, les patients n’évolueront pas tous vers les formes sévères de la maladie. Le microbiote intestinal est un cofacteur déterminant dans la sévérité de la MAF. Parmi les métabolites fécaux entre des souris recevant le microbiote intestinal de patients avec des lésions sévères ou non, les acides biliaires ont été identifiés comme les plus discriminants. Le récepteur aux acides biliaires TGR5, exprimé sur les cellules de Kupffer, favorise leur profil anti-inflammatoire.Nous avons évalué l’impact du récepteur TGR5 dans la MAF chez des souris déficientes pour ce récepteur. La déficience en TGR5 aggrave la MAF, sans passer par une modulation de la cellule de Kupffer. C’est en fait le microbiote intestinal qui est impacté chez les souris déficientes pour TGR5, et qui médie cette aggravation.Par ailleurs, afin de moduler le microbiote intestinal au cours de la MAF, nous avons évalué le rôle de la pectine, qui favorise la croissance de certaines bactéries et peut chélater les acides biliaires. Malgré ses propriétés chélatantes, ce sont bien les modifications du microbiote intestinal induites par la pectine qui jouent un rôle protecteur et curatif dans la MAF.Ces différentes études devraient permettre d’identifier des cibles thérapeutiques potentiellement applicables chez des patients alcooliques et basées sur la modulation du microbiote intestinal. / Alcoholic liver disease (ALD) includes all the liver injuries occurring as a result of excessive and chronic alcohol consumption. Nevertheless, among heavy drinker, only a subset of individuals will develop severe liver injury. Intestinal microbiota was identified as a major player in the mechanisms involved in ALD. Moreover, bile acids were the most discriminant faecal metabolites between mice with or without liver injury. The bile acids receptor TGR5, which is expressed on Kupffer cells, promotes their anti-inflammatory profile.We assessed the role of bile acids receptor TGR5 in ALD using TGR5-deficient mice. TGR5-deficiency worsens ALD, but without modulating the Kupffer cells profile. However, intestinal microbiota is impaired in TGR5-deficient mice, and this is responsible for ALD worsening.Furthermore, in order to modulate the intestinal microbiota during ALD, we assessed the role of pectin, which is known to promote the growth of certain bacteria and that is a bile acids sequestrant. Despite its sequestrant properties, pectin-induced changes in intestinal microbiota play a protective and curative role in ALD.These studies will allow the identification of new therapeutic targets that could be used for alcoholic patients, using intestinal microbiota modulation.
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Elektrochemická oxidace žlučových kyselin na elektrodách na bázi uhlíku. Možnosti využití v elektroanalýze. / Electrochemical oxidation of Bile Acids on Carbon Based Electrodes. The Possible Use in Electroanalysis.Klouda, Jan January 2015 (has links)
The goal of this master's thesis was to examine the possibility of oxidation of seven selected bile acids and evaluate whether such processes are suitable for analytical purposes. The secondary goal was to describe the oxidation products of bile acid electrolysis. The experiments were carried out in a non-aqueous medium of acetonitrile and in a mixed medium of acetonitrile:water using linear sweep and cyclic voltammetry. The working electrode materials employed for voltammetric experiments were: highly oriented pyrolytic graphite, -cyclodextrin modified glassy carbon and boron doped diamond. Preparative electrolysis was carried out on a platinum electrode in the non-aqueous medium of acetonitrile. Experiments have shown that neither the highly oriented pyrolytic graphite electrode nor the -cyclodextrin modified glassy carbon electrode are suitable for analytical purposes under conditions used. The results achieved on the boron doped diamond electrode, on the other hand, have not yet been described in the literature. Primary bile acids cholic and chenodeoxycholic were oxidized at approximately 0.5 V lower potential in the mixed medium of acetonitrile:water than in the papers using carbon electrodes published until now. Products of oxidation on the platinum electrode were separated by TLC and...
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AN ASSESSMENT OF CHEMICAL TRACERS FOR TRACKING FECAL CONTAMINATION OF WATER SOURCES AND HOW THEY CAN BE APPLIED TO OLIGOTROPHIC WATER BODIESMhandu, Munyaradzi Gibson January 2021 (has links)
This study assessed the chemical substances that can be used to investigate fecal contamination of surface waters and how they can be used to indicate and trace fecal contamination in oligotrophic rivers of Northern Sweden. It was found that, from previous studies, several chemicals can be used to trace fecal contamination of surface water, and these include pharmaceuticals, personal care products, sterols, stanols and bile acids. Pharmaceuticals have been successfully used to indicate fecal contamination in many tropical countries and some countries in the cold regions and thus can also be applied to oligotrophic rivers. Sterols, stanols and bile acids make it possible to accurately indicate and trace the different sources of fecal contamination and can also be used to distinguish between the different organisms from which those sterols and bile acids emanate. For these groups of chemicals analytical methods such as chromatography and mass spectrometry are used to decipher the different chemicals in the test samples of water or sediment. Overall, these methods can be used concurrently but the sterols and bile acids have more specificity compared to the pharmaceuticals and personal care products / <p>2021-07-06</p>
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Self-assembled Two-component Organic Tubes: Structures And ApplicationsLiang, Wenlang 01 January 2013 (has links)
Bile acids are physiologically important metabolites, which are synthesized in liver as the end products of cholesterol metabolism and then secreted into the intestines. They play a critical role in the digestion and absorption of fats and fat-soluble vitamins through emulsifications. The amphipathic and chiral nature of bile acids makes their unique building blocks for assembling supramolecular structures including vesicles, fibers, ribbons and hollow tubes. Lithocholic acid (LCA) is a secondary bile acid. Our studies show LCA can selfassemble into helical tubes in aqueous solution by the linear aggregation and fusion of vesicles. The objective of this dissertation is to tune the structure of helical tubes and functionalize them by the co-assembly of ionic LCA and cationic cetyltrimethylammonium bromide (CTAB) and ionic LCA and cationic cyanine dye (CD), respectively. The first part of this dissertation focuses on the ionic-assembly of LCA and CTAB to synthesize the helical tubes with varied diameters and pitches. Our studies show that LCA and CTAB can self-assemble into helical tubes in NH4OH aqueous solution. The diameter of the helical tubes can be changed by adjusting the molar ratio of LCA and CTAB. The pitch of the helical tubes can be tuned by varying NH4OH concentrations. Differential scanning calorimetry studies indicate that there is a homogeneous composition distribution in the LCA/CTAB helical tubes. X-ray diffraction analysis studies show that the helical tubes have multibilayer walls with an average d-spacing of 4.11nm. We demonstrate that the helical tubes with varied diameters and pitches can be transformed into helical silica through the sol-gel transcription of tetraethoxysilane (TEOS). The second part of this dissertation is to use the ionic self-assembly of LCA and CD to design light-harvesting tubes iv by mimicking green sulfur bacteria that are known to be a highly efficient photosynthesizer. Xray diffraction and optical spectra show that LCA and CD can co-assemble into J- or Haggregate tubes, depending the condition under which the self-assembly occurs. We demonstrate the feasibility of using the J-aggregate nanotubes in the sensitive and selective detection of mercury (II) ions by the photoinduced electron transfer under sunlight. The presence of mercury (II) ions in aqueous solution could be detected for concentrations as low as 10 pM.
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Biomimetic Strategies for Electrophoretic Deposition of Polymers and CompositesZhao, Qinfu January 2022 (has links)
The global market for fluoropolymers, including polytetrafluoroethylene (PTFE), polyvinylidene fluoride (PVDF), and poly(vinylidene fluoride-co-hexafluoropropylene) (PVDF-HFP), is growing rapidly due to their copious applications in the construction, automotive, medical, chemical, and electrical industries. Fluoropolymers owe their popularity partly to their excellent chemical and thermal stability and useful mechanical, piezoelectric, and ferroelectric properties. They are made into films or coatings that are used for corrosion protection or surface property enhancement. Electrophoretic deposition (EPD) has generated increasing interest in manufacturing advanced films for various applications due to its low cost, versatility, simple apparatus, and good film quality compared with other deposition techniques like dip coating, spin coating, electrospinning, or spay coating. Moreover, EPD facilitates uniform deposition on the substrates of complex shapes at a high deposition rate.
The aim of this research is to develop novel biomimetic strategies for fabricating polymer films and their composite films with multifunctional particles through EPD. This method involves the electrophoresis of charged particles in a stable colloidal suspension towards an electrode, forming deposition. Fluoropolymers, however, are electrically neutral and chemically inert, and their EPD presents difficulties. Therefore, successful EPD depends on understanding how to modify the surface of polymer particles using advanced biosurfactants to impart charge and form a well dispersed, stable colloidal suspension.
One strategy is to leverage the unique dispersing power of bile acids and salts as biosurfactants for EPD of PTFE and PVDF films and composite films. When doing so, it was found that the amphiphilic structure of bile salts such as sodium deoxycholate (DChNa) facilitated adsorption on the chemically inert, hydrophobic surfaces of PTFE, diamond, and carbon dots. In this strategy, DChNa acted as a charging, dispersing, film-forming agent for the co-deposition of PTFE composite films from an aqueous suspension. Water insoluble bile acids (BAs) were found to be biosurfactants for the EPD of PTFE and PVDF from organic solvents, in which lithocholic acid (LCA) was used as a co-dispersant for the fabrication of composite PTFE-diamond coatings and PTFE coatings provided corrosion protection for stainless steel in 3% NaCl solutions. The dispersing performance of four other bile acids, chenodeoxycholic acid (CDCA), deoxycholic acid (DCA), ursodeoxycholic acid (UDCA), and cholic acid (ChA), was analyzed and compared with LCA on the deposition performance of PVDF. It was found that the PVDF deposition yield obtained using different BAs increased in the order of LCA<CDCA<DCA<UDCA<ChA. This was attributed to the difference in number, position, and orientation of OH groups in the structures of the BAs.
Another biomimetic strategy for the EPD of polymers and composites was inspired by the strong adsorption of mussel protein on rock surfaces in sea water. Catecholate-type molecules, caffeic acid (CA) and catechol violet (CV), were found to be biosurfactants for dispersing, charging, and depositing PVDF films and composites. Analyses of the deposition yield data, the chemical structure of the CA and CV, and the microstructure and composition of the films suggested that the aromatic rings on the CA and CV had hydrophobic interactions with the PVDF particles and that the phenolic groups formed bidentate chelating or bridging bonding to inorganic particle surfaces. The study demonstrated the feasibility of co-depositing PVDF with nanoparticles of TiO2, MnO2, and NiFe2O4. CA was also used for preparing PVDF-HFP particles and as a co-dispersant for the co-deposition of PVDF-HFP with NiFe2O4 and CuFe2O4 nanoparticles in order to make composite films that combine the ferrimagnetic properties of spinel ferrites with the multifunctional properties of ferroelectric polymers. / Dissertation / Doctor of Philosophy (PhD)
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Characterizing Bile Acid Association as a Ligand and in Micellization.Werry, Brian Scott 21 February 2014 (has links)
No description available.
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Microbial Derived Modulators of Host Health and BehaviorMavros, Chrystal Felicia January 2024 (has links)
The human body is home to complex microbial communities that are fundamental to our physiology. Utilizing mouse models, behavior assays, gene expression analyses, and probiotic interventions, this research explores the intricate relationship between the gut microbiome, the central nervous system, and the immune system.
I discuss a strain of Escherichia coli Nissle engineered to produce serotonin, revealing its impact on gut function and immune response. I also evaluate butyrate’s potential to alleviate symptoms of Fragile X Syndrome, highlighting the gut-brain axis. Additionally, I study a strain of Bifidobacterium adolescentis and its role in metabolizing bile acids and modulating host immune cells and stress.
Collectively, these studies address the complex interplay between the gut microbiome and host health and behavior, illuminating the therapeutic potential of microbiome manipulation and setting the stage for novel interventions in neurodevelopmental disorders and immune function regulation.
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Polyamides and polyesters made of bile acids in the main chainIvanysenko, Olga 09 1900 (has links)
La préparation de polymères à base d’acides biliaires, molécules biologiques, a attiré
l'attention des chercheurs en raison des applications potentielles dans les domaines
biomédicaux et pharmaceutiques. L’objectif de ce travail est de synthétiser de nouveaux
biopolymères dont la chaîne principale est constituée d’unités d’acides biliaires. La
polymérisation par étapes a été adoptée dans ce projet afin de préparer les deux principales classes de polymères utilisés en fibres textiles: les polyamides et les polyesters.
Des monomères hétéro-fonctionnels à base d’acides biliaires ont été synthétisés et
utilisés afin de surmonter le déséquilibre stoechiométrique lors de la polymérisation par étapes. Le dérivé de l’acide lithocholique modifié par une fonction amine et un groupement carboxylique protégé a été polymérisé en masse à températures élevées. Les polyamides obtenus sont très peu solubles dans les solvants organiques. Des polyamides et des polyesters solubles en milieu organique ont pu être obtenus dans des conditions modérées en utilisant l’acide cholique modifié par des groupements azide et alcyne. La polymérisation a été réalisée par cycloaddition azoture-alcyne catalysée par l'intermédiaire du cuivre(Ι) avec deux systèmes catalytiques différents, le bromure de cuivre(I) et le sulfate de cuivre(II). Seul le bromure de cuivre(Ι) s’est avéré être un catalyseur efficace pour le système, permettant la préparation des polymères avec un degré de polymérisation égale à 50 et une distribution monomodale de masse moléculaire (PDI ˂ 1.7). Les polymères synthétisés à base d'acide cholique sont thermiquement stables (307 °C ≤ Td ≤ 372 °C) avec des températures de transition vitreuse élevées (137 °C ≤ Tg ≤ 167 °C) et modules de Young au-dessus de 280 MPa, dépendamment de la nature chimique du lien. / Bile acids have drawn attention in the synthesis of polymers for biomedical and
pharmaceutical applications due to their natural origin. The objective of this work is to synthesize main-chain bile acid-based polymers. The step-growth polymerization was used to prepare two important classes of polymers used in textile fibers, polyamides and polyesters.
Heterofunctional bile acid-based monomers were synthesized and used in order to
overcome stoichiometric imbalances during step-growth polymerization. The lithocholic
acid derivative bearing amine and protected carboxylic functional groups was polymerized
in bulk at high temperatures, yielding polyamides that were poorly soluble in common
organic solvents. Soluble triazole-linked polyamides and polyesters were obtained when the cholic acid derivative bearing azide and alkyne functional groups was polymerized under mild conditions via copper(Ι)-catalyzed azide-alkyne cycloaddition. Two different catalytic
systems, copper(Ι) bromide and copper(ΙΙ) sulfate, were tested. Only copper(Ι) bromide
proved to be an effective catalyst for the system, allowing the synthesis of the polymers with a degree of polymerization of ca. 50 and an unimodal molecular weight distribution(PDI ˂ 1.7). The main-chain cholic acid-based polymers are thermally stable (307 °C ≤ Td ≤ 372 °C) with high glass transition temperatures (137 °C ≤ Tg ≤ 167 °C) and Young’s moduli in excess of 280 MPa, depending on the chemical structure of the linker.
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The Effect of Cobalt Protoporphyrin and Cobalt Chloride on Heme Oxygenase Expression and Protection from Deoxycholate-Induced ApoptosisLawson, Tina 23 July 2010 (has links)
The inner surface of the stomach is lined by a mucous membrane known as the gastric mucosa. The integrity of the gastric mucosa is critical for protecting the stomach from the low pH and proteolytic environment within the lumen. Both clinically and experimentally, exposure of gastric mucosal cells to bile salts is known to cause injury. Bile salts present in duodenogastric reflux are thought to play a significant role in gastric ulcer formation and alkaline gastritis. In vitro, studies using physiologic concentrations of the secondary bile salt, deoxycholic acid, indicate that bile salts can induce apoptosis in cultured human gastric epithelial cells in a caspase-dependent manner. Therefore, there is interest in developing approaches that can protect gastric cells from bile salt-induced damage. It has been shown that induction of the stress protein, heme oxygenase-1, can provide protection against apoptosis. Therefore, the objective of this study was to test the hypotheses that heme oxygenase-1 expression could be induced in human gastric epithelial cells and that furthermore; this would provide protection from deoxycholic acid-induced apoptosis. Heme oxygenase-1 expression was induced pharmacologically or by introduction of a plasmid expressing heme oxygenase-1 into the gastric epithelial cell line, AGS. Induction of heme oxygenase-1 prior to challenge with deoxycholate reduced apoptotic-associated morphological changes, DNA fragmentation, the appearance of oligonucleosomes in the cytoplasm, and activation of caspase-3 and caspase-9. Based on these results, it was concluded that expression of heme oxygenase-1, or the introduction of its products, can provide protection to human gastric epithelial cells against sodium deoxycholic acid induced-apoptosis.
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Regulation of Pancreatic α and β Cell Function by the Bile Acid Receptor TGR5Prasanna Kumar, Divya 01 January 2014 (has links)
The discovery that bile acids act as endogenous ligands of the membrane receptor TGR5 and the nuclear receptor FXR increased their significance as regulators of cholesterol, glucose and energy metabolism. Activation of TGR5, expressed on enteroendocrine L cells, by bile acids caused secretion of GLP-1, which stimulates insulin secretion from pancreatic β cells. Expression of TGR5 on pancreatic islet cells and the direct effect of bile acids on the endocrine functions of pancreas, however, are not fully understood. The aim of this study was to identify expression of TGR5 in pancreatic islet cells and determine the effect of bile acids on insulin secretion. Expression of TGR5 was identified by quantitative PCR and western blot in islets from human and mouse, and in α (αTC1-6) and β (MIN6) cells. Release of insulin, glucagon and GLP-1 were measured by ELISA. The signaling pathways coupled to TGR5 activation were identified by direct measurements such as stimulation of G proteins, adenylyl cyclase activity, PI hydrolysis and intracellular Ca2+ in response to bile acids; and confirmed by the use of selective inhibitors that block specific steps in the signaling pathway. Our studies identified expression of TGR5 receptors in β cells and demonstrated that activation of these receptors by both pharmacological ligands (oleanolic acid (OA) and INT-777) and physiological ligand (lithocholic acid, LCA) induced insulin secretion. TGR5 receptors are also expressed in α cells and, activation of TGR5 by OA, INT-777 and LCA at 5 mM glucose induced release of glucagon, which is processed from proglucagon by the selective expression of prohormone convertase 2 (PC2). However, under hyperglycemia, activation of TGR5 in α cells augmented the glucose-induced increase in GLP-1 secretion, which in turn, stimulated insulin secretion. Secretion of GLP-1 from α cells reflected TGR5-mediated increase in PC1 promoter activity and PC1 expression, which selectively converts proglucagon to GLP-1. The signaling pathway activated by TGR5 to mediate insulin and GLP-1 secretion involved Gs/cAMP/Epac/PLC-ε/Ca2+. These results provide insights into the mechanisms involved in the regulation of pancreatic α and β cell function by bile acids and may lead to new therapeutic avenues for the treatment of diabetes.
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