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101	Development of new radical processes : approaches toward the synthesis of Eucophylline. / Développement de nouveaux processus radicalaires : application à la synthèse de l'Eucophylline. Mohammed, Shireen Rashid 08 December 2014 (has links) L’objectif de ce travail a consisté en le développement de nouveaux processus multi-composant radicalaires et leur application en synthèse organique. Des carbo-alcénylation d'oléfines ont ainsi été réalisées avec de nouveaux précurseurs de radicaux, des oléfines diverses, en présence de Z-diphénylsulfonyléthylène comme accepteur terminal. Les conditions de la réaction ont été optimisées, en introduisant notamment la diphénylsulfonylhydrazine comme amorceur de radicaux sous irradiation UV, et substitut au couteux DTBHN. Des conditions sans étain ont également été étudiées avec l’objectif de remplacer le réactif (Bu3Sn)2 par des radicaux silylés. Le tris (triméthylsilyl)silylthiopropene a ainsi été testé avec succès en tant qu'agent de propagation des chaînes radicalaires. A l’issue de ce travail méthodologique, nous avons développé une stratégie de synthèse de l'Eucophylline, un alcaloïde isolé de Leuconotis griffithii, dont le squelette tétracyclique a été élaboré sur la base d’une réaction de carbo-oximation radicalaire d’oléfine. Ce processus multicomposant, suivi d’une réduction de la fonction oxime et d’une lactamisation offre une voie d’accès rapide au motif bicyclo[3.3.1]lactame, intermédiaire-clé de la synthèse. Une réaction de type Friedländer entre ce lactame et un ortho-aminobenzonitrile a permis d’accéder au squelette tetrahydrobenzo[1,8]naphthyridine de l'Eucophylline. La synthèse du composé modèle a enfin été complétée par l’introduction du substituant vinylique par un couplage de Heck. / The aim of this work was to develop new radical multi-component processes and their application in organic synthesis. Carbo-alkenylation processes were thus performed with new radical precursors, different olefins, in the presence of Z-diphenylsulfonylethylene as a terminal acceptor. Reaction conditions have also been optimized, including the diphenylsulfonylhydrazine as a radical initiator under U.V. irradiation, and substitute to the costly DTBHN. Tin-free conditions were also screened with the goal of replacing (Bu3Sn)2 with silyl radicals. Tris(trimethylsilyl)silylthiopropene was tested with success as a radical chain carrier. After this methodology studies, we developed a strategy toward the synthesis of Eucophylline, an alcaloid isolated from Leuconotis griffithii, which tetracyclic skeleton was elaborated based on a carbo-oximation of olefin. This multicomponent process, followed by a reduction of the oxime function and a lactamization offered a fast access to the bicyclo[3.3.1]lactam, a key-intermediate in the synthesis. A Friedländer-type reaction between this lactam and an ortho-aminobenzonitrile allowed an access to the Eucophylline tetrahydrobenzo[1,8]naphthyridine skeleton. The synthesis of the model compound was finally completed with the introduction of the vinylic substituent through a Heck coupling. Réactions radicalaires multi-composants Carbo-alcénylation d'alcènes Eucophylline Lactame ponté Réaction de Friedländer Multi-component radical reactions (MCR), Carbo-alkenylation reactions Eucophylline alkaloid Bridgehead lactam Friedländer reaction
102	Enantioselective C(sp3)-H Arylation and Development of a Modular C(sp3)-H Alkenylation / Activation C(sp3)-H Enantiosélective et Développement d'une Alcenylation C(sp3)-H Modulaire Holstein, Philipp 28 November 2014 (has links) Récemment, l'activation C-H catalysée par des métaux de transition est devenue un outil performant pour construire des liaisons carbone-carbone et carbone hétéroatome à partir de liaisons C-H omniprésentes dans les molécules organiques. Bien que l'activation des liaisons C-H aromatiques ait été largement étudiée ces dernières années, celle des liaisons C-H aliphatiques représente encore un domaine faiblement exploré. Notre équipe s'est depuis plusieurs années intéressée au développement méthodologique de l'activation C(sp3)-H et à son application en synthèse de produits naturels et molécules bioactives. Dans la continuité des récents travaux sur la version asymétrique de cette réaction, cette thèse décrit le développement et la synthèse de nouveaux ligands du type Binepine. Ces ligands chiraux et monodentates nous ont permis de réaliser la synthèse d'indanes chiraux possédant un centre asymétrique quaternaire, de manière hautement énantio- et diastéréosélective. Cette réaction présente comme avantages l'utilisation d'une faible charge catalytique et d'une température de réaction inférieure à 100 °C, sans aucun additif. Le champ d'application de la réaction inclut notamment l'activation des liaisons C-H d'un groupement méthylène, donnant ainsi accès à des systèmes fusionnés, tricycliques. La construction de molécules non-aromatiques via une alcénylation C-H intramoléculaire a été récemment décrite et s'avère très prometteuse pour la synthèse de produits naturels saturés. Dans la continuité de ces travaux innovants, nous avons développé la synthèse de γ-lactames à partir de bromoalcènes acycliques. Cette nouvelle réaction permet de construire de manière simple et efficace des hétérocycles a cinq chainons de façon modulaire, donnant ainsi la possibilité d'envisager des nouvelles déconnections rétrosynthétiques, complémentaires des méthodes déjà établies. Cette nouvelle méthode a pu être appliquée à la synthèse totale de l'alcaloïde marin Plakoridine A, dont la structure centrale cyclique a été synthétisée en quatre étapes avec un rendement global de 37% / Recently, transition-metal-catalyzed C-H activation has emerged as a powerful tool to transform stable C-H bonds into carbon-carbon or carbon-heteroatom bonds. While the activation of aromatic C-H bonds has seen a tremendous development, less effort has been devoted to the more challenging activation of aliphatic C-H bonds. Our group has a long-standing interest in the development of C(sp3)-H activation reactions and their application in the synthesis of natural products and bioactive compounds. In line with previous efforts to develop an asymmetric C(sp3)-H activation, the herein presented work details the synthesis of new Binepine ligands. These monodentate, chiral ligands enabled us to realize a highly dia- and enantioselective C(sp3)-H activation reaction allowing the construction of chiral quaternary carbon centers. Strong points of this robust method are the low catalyst loading, the low reaction temperature and the absence of additives. The substrate scope includes the rare activation of methylene C-H bonds leading to fused tricyclic carbocycles and heterocycles. The construction of non-aromatic molecules through intramolecular C-H alkenylation was recently disclosed and has great potential for the construction of saturated natural products. Based on seminal work, we have developed the synthesis of valuable γ- lactams from acyclic bromoalkenes. This new methodology offers a powerful way to build simple, five-membered N heterocycles in a modular fashion. Notably, it enables a new retrosynthetic disconnection which is complementary to conventional approaches. Finally, we set out to showcase its utility as key step in the total synthesis of the pyrrolidine alkaloid Plakoridine A. The cyclic core structure was accessed in four steps and 37% overall yield Activation C-H Catalyse asymétrique Binepine Palladium Synthèse totale Γ-lactame Plakoridine A C-H activation Asymmetric catalysis Binepine Palladium Total synthesis Γ-lactam Plakoridine A 547
103	Biological and Pharmacological Factor that Influence the Selection of Antibiotic Resistance Gustafsson, Ingegerd January 2003 (has links) <p>Antibiotic treatment causes an ecological disturbance on the human microflora. Four commensal bacteria: E. coli, enterococci, a-streptococci and coagulase-negative staphylococci, from patients with extensive, high antibiotic usage were investigated with regard to resistance pattern and mutation frequency. Among 193 investigated strains it was found that high antibiotic usage selected for resistant bacteria and enriched for bacteria with a small but significantly increased mutation frequency. </p><p>The relative biological fitness cost of resistance in <i>Staphylococcus epidermidis</i> was assessed in a human in vivo model where the indigenous flora was present. In vitro data of the bacterial growth rate correlated well to in vivo fitness assayed in the competition experiments on skin. </p><p>An in vitro kinetic model was shown to be a useful tool to establish the pharmacokinetic and pharmacodynamic (PK/PD) indices for efficacy of antibiotics. It was confirmed that the time, when the concentration exceeds the minimal inhibitory concentration (MIC), correlates with efficacy for b-lactam antibiotics. To achieve maximal killing for penicillin-resistant pneumococci, with an MIC of 2 mg/L, the peak concentration was also of importance. </p><p>Suboptimal dosing regimen facilitates selection of resistance. Penicillin-resistant pneumococci were easily selected in a mixed population with penicillin-sensitive, -intermediate and -resistant pneumococci in an in vitro kinetic model. The selection of the resistant strain was prevented when the benzylpenicillin concentration exceeded the MIC for approximately 50% of 24 h.</p> Microbiology Human microflora antibiotic resistance selection mutation frequency biological fitness pharmacokinetics pharmacodynamics β-lactam antibiotics suboptimal dosing regimen Mikrobiologi Microbiology Mikrobiologi
104	Antibiotic-induced Bacterial Toxin Release – Inhibition by Protein Synthesis Inhibitors Hjerdt-Goscinski, Gunilla January 2004 (has links) <p>Toxic products, such as endotoxin from the gram-negative and exotoxin from the gram-positive bacteria, are the most important initiators of the inflammatory host response in sepsis. In addition to antibacterial treatment, numerous attempts have been made to interfere with the exaggerated proinflammatory cascade initiated by the toxins. As most antitoxic and anti-inflammatory agents have shown no clear efficacy, an attractive alternative has been to prevent or minimise their release. Therefore, it was of interest to further study the antibiotic-induced release of toxins after exposure to antibiotics used for the treatment of the most severe infections, especially if protein synthesis inhibitors could reduce the release induced by PBP 3-specific β-lactam antibiotics.</p><p>There were significant reductions in endotoxin release from gram-negative bacteria when the combination of the PBP 3-specific β-lactam antibiotic, cefuroxime, and the protein synthesis inhibitor, tobramycin, was compared with cefuroxime alone. Increasing doses of tobramycin reduced endotoxin release and increased the killing rate. In a kinetic <i>in vitro</i> model the endotoxin release from <i>E.coli</i> was higher after the second dose of cefuroxime. Nevertheless, it was reduced after addition of tobramycin.</p><p>No binding of tobramycin to endotoxin was observed, either <i>in vivo</i> or <i>in vitro</i>. In a porcine sepsis model, a possible anti-inflammatory effect of ceftazidime and tobramycin, expressed as late cytokine inhibition, was seen.</p><p>The protein synthesis inhibitor, clindamycin, released less streptococcal pyrogenic exotoxin A (SpeA) from a group A streptococcus strain than penicillin, and addition of clindamycin to penicillin resulted in less toxin production than penicillin alone. The SpeA production was dependent on the bacterial number at the start of treatment. Higher doses of penicillin also led to less SpeA. </p><p>The choice of antibiotic class and dose may be important in the severely ill septic patient in whom an additional toxin release could be deleterious. A combination of a β-lactam antibiotic and a protein synthesis inhibitor seems beneficial but further investigations are needed.</p> Communicable diseases Endotoxin LPS exotoxin SpeA penicillin-binding protein aminoglycosides clindamycin β-lactam antibiotics severe sepsis septic shock Infektionssjukdomar Infectious diseases Infektionssjukdomar
105	Evasion and Attack: Structural Studies of a Bacterial Albumin-binding Protein and of a Cephalosporin Biosynthetic Enzyme Lejon, Sara January 2008 (has links) <p>This thesis describes the crystal structures of two proteins in the context of combatting bacterial infections. The GA module is a bacterial albumin-binding domain from a surface protein expressed by pathogenic strains of the human commensal bacterium <i>Finegoldia magna</i>. The structure of the GA module in complex with human serum albumin (HSA) provides insights into bacterial immune evasion, where pathogenicity is acquired by the bacterial cell through the ability to coat (and disguise) itself with serum proteins. The structure shows binding of the GA module to HSA in the presence of fatty acids, and reveals interactions responsible for the host range specificity of the invading bacterium. The complex resulting from binding of the GA module to HSA readily forms stable crystals that permit structural studies of drug binding to HSA. This was exploited to study the specific binding of the drug naproxen to the albumin molecule.</p><p>Antibiotics play a major role in controlling infections by attacking invading bacteria. The enzyme deacetylcephalosporin C acetyltransferase (DAC-AT) catalyses the last step in the biosynthesis of the beta-lactam antibiotic cephalosporin C, one of the clinically most important antibiotics in current use. The enzyme uses acetyl coenzyme A as cofactor to acetylate a biosynthetic intermediate. Structures of DAC-AT in complexes with reaction intermediates have been determined. The structures suggest that the acetyl transfer reaction proceeds through a double displacement mechanism, with acetylation of a catalytic serine by the cofactor through a suggested tetrahedral transition state, followed by acetyl transfer to the intermediate through a second suggested tetrahedral transition state. The structure of DAC-AT yields valuable information for the continued study of cephalosporin biosynthesis in the context of developing new beta-lactam compounds.</p> human serum albumin GA module albumin-binding Finegoldia magna cephalosporin C antibiotic beta-lactam biosynthesis Acremonium chrysogenum X-ray crystallography Structural biology Strukturbiologi
106	Synthesis and biological evaluation of Bicyclic β-Lactams and 2-Pyridinones : Pilicides Targeting Pilus Biogenesis in Pathogenic Bacteria Emtenäs, Hans January 2003 (has links) New methods have been developed for the synthesis of bicyclic β-lactams and 2-pyridinones by combining acyl Meldrum’s acids and Δ2-thiazolines. The 2-pyridinones were synthesised both in solution using conventional heating or microwave assisted heating as well as by solid supported chemistry. The compounds (pilicides) were designed to interfere with the assembly of pili in uropathogenic E. coli by inhibiting the periplasmic chaperones. The affinity of the pilicides to the chaperones was investigated with surface plasmon resonance technique (Biacore) and with relaxation-edited 1H NMR spectroscopy experiments. Finally, the pilicides were investigated for their ability to inhibit pili formation in uropathogenic E. coli in a hemagglutination assay, where members of the 2-pyridinone family proved to be able to cause depiliation. Organic chemistry β-lactam 2-pyridinone 2-pyridone Meldrum’s acid Δ2-thiazoline solid-phase synthesis microwave assisted synthesis antibacterial pili pilicide Organisk kemi Organic chemistry Organisk kemi
107	Antibiotic-induced Bacterial Toxin Release – Inhibition by Protein Synthesis Inhibitors Hjerdt-Goscinski, Gunilla January 2004 (has links) Toxic products, such as endotoxin from the gram-negative and exotoxin from the gram-positive bacteria, are the most important initiators of the inflammatory host response in sepsis. In addition to antibacterial treatment, numerous attempts have been made to interfere with the exaggerated proinflammatory cascade initiated by the toxins. As most antitoxic and anti-inflammatory agents have shown no clear efficacy, an attractive alternative has been to prevent or minimise their release. Therefore, it was of interest to further study the antibiotic-induced release of toxins after exposure to antibiotics used for the treatment of the most severe infections, especially if protein synthesis inhibitors could reduce the release induced by PBP 3-specific β-lactam antibiotics. There were significant reductions in endotoxin release from gram-negative bacteria when the combination of the PBP 3-specific β-lactam antibiotic, cefuroxime, and the protein synthesis inhibitor, tobramycin, was compared with cefuroxime alone. Increasing doses of tobramycin reduced endotoxin release and increased the killing rate. In a kinetic in vitro model the endotoxin release from E.coli was higher after the second dose of cefuroxime. Nevertheless, it was reduced after addition of tobramycin. No binding of tobramycin to endotoxin was observed, either in vivo or in vitro. In a porcine sepsis model, a possible anti-inflammatory effect of ceftazidime and tobramycin, expressed as late cytokine inhibition, was seen. The protein synthesis inhibitor, clindamycin, released less streptococcal pyrogenic exotoxin A (SpeA) from a group A streptococcus strain than penicillin, and addition of clindamycin to penicillin resulted in less toxin production than penicillin alone. The SpeA production was dependent on the bacterial number at the start of treatment. Higher doses of penicillin also led to less SpeA. The choice of antibiotic class and dose may be important in the severely ill septic patient in whom an additional toxin release could be deleterious. A combination of a β-lactam antibiotic and a protein synthesis inhibitor seems beneficial but further investigations are needed. Communicable diseases Endotoxin LPS exotoxin SpeA penicillin-binding protein aminoglycosides clindamycin β-lactam antibiotics severe sepsis septic shock Infektionssjukdomar Infectious diseases Infektionssjukdomar
108	Evasion and Attack: Structural Studies of a Bacterial Albumin-binding Protein and of a Cephalosporin Biosynthetic Enzyme Lejon, Sara January 2008 (has links) This thesis describes the crystal structures of two proteins in the context of combatting bacterial infections. The GA module is a bacterial albumin-binding domain from a surface protein expressed by pathogenic strains of the human commensal bacterium Finegoldia magna. The structure of the GA module in complex with human serum albumin (HSA) provides insights into bacterial immune evasion, where pathogenicity is acquired by the bacterial cell through the ability to coat (and disguise) itself with serum proteins. The structure shows binding of the GA module to HSA in the presence of fatty acids, and reveals interactions responsible for the host range specificity of the invading bacterium. The complex resulting from binding of the GA module to HSA readily forms stable crystals that permit structural studies of drug binding to HSA. This was exploited to study the specific binding of the drug naproxen to the albumin molecule. Antibiotics play a major role in controlling infections by attacking invading bacteria. The enzyme deacetylcephalosporin C acetyltransferase (DAC-AT) catalyses the last step in the biosynthesis of the beta-lactam antibiotic cephalosporin C, one of the clinically most important antibiotics in current use. The enzyme uses acetyl coenzyme A as cofactor to acetylate a biosynthetic intermediate. Structures of DAC-AT in complexes with reaction intermediates have been determined. The structures suggest that the acetyl transfer reaction proceeds through a double displacement mechanism, with acetylation of a catalytic serine by the cofactor through a suggested tetrahedral transition state, followed by acetyl transfer to the intermediate through a second suggested tetrahedral transition state. The structure of DAC-AT yields valuable information for the continued study of cephalosporin biosynthesis in the context of developing new beta-lactam compounds. human serum albumin GA module albumin-binding Finegoldia magna cephalosporin C antibiotic beta-lactam biosynthesis Acremonium chrysogenum X-ray crystallography Structural biology Strukturbiologi
109	Biological and Pharmacological Factor that Influence the Selection of Antibiotic Resistance Gustafsson, Ingegerd January 2003 (has links) Antibiotic treatment causes an ecological disturbance on the human microflora. Four commensal bacteria: E. coli, enterococci, a-streptococci and coagulase-negative staphylococci, from patients with extensive, high antibiotic usage were investigated with regard to resistance pattern and mutation frequency. Among 193 investigated strains it was found that high antibiotic usage selected for resistant bacteria and enriched for bacteria with a small but significantly increased mutation frequency. The relative biological fitness cost of resistance in Staphylococcus epidermidis was assessed in a human in vivo model where the indigenous flora was present. In vitro data of the bacterial growth rate correlated well to in vivo fitness assayed in the competition experiments on skin. An in vitro kinetic model was shown to be a useful tool to establish the pharmacokinetic and pharmacodynamic (PK/PD) indices for efficacy of antibiotics. It was confirmed that the time, when the concentration exceeds the minimal inhibitory concentration (MIC), correlates with efficacy for b-lactam antibiotics. To achieve maximal killing for penicillin-resistant pneumococci, with an MIC of 2 mg/L, the peak concentration was also of importance. Suboptimal dosing regimen facilitates selection of resistance. Penicillin-resistant pneumococci were easily selected in a mixed population with penicillin-sensitive, -intermediate and -resistant pneumococci in an in vitro kinetic model. The selection of the resistant strain was prevented when the benzylpenicillin concentration exceeded the MIC for approximately 50% of 24 h. Microbiology Human microflora antibiotic resistance selection mutation frequency biological fitness pharmacokinetics pharmacodynamics β-lactam antibiotics suboptimal dosing regimen Mikrobiologi Microbiology Mikrobiologi
110	New Diazo Reagents and Applications of β-Lactones for Synthesis and Biological Evaluation of Natural Products Chamni, Supakarn 2011 December 1900 (has links) Natural products are essential tools for basic cellular studies leading to the identification of medically relevant protein targets and the discovery of potential therapeutic agents. We have developed a set of second generation diazo reagents with small steric footprints, namely an alpha-trifluoroethyl (HTFB) diazo reagent, for simultaneous arming and SAR studies of bioactive natural products. The Rh(II)-catalyzed O-H insertions of several alcohol-containing natural products, including the potent translation inhibitor lactimidomycin, are investigated and useful reactivity and both chemo- and site- (chemosite) selectivities are observed. The alpha-trifluoroethyl diazo reagents (HTFB) shows clear differences in the IL-2 reporter assay with FK506 derivatives and provides greater retention of biological activity in a hMetAP2 proliferation assay of fumagillol derivatives compared to the first generation pbromophenyl diazo reagent (HBPA). The synthetic utilities of the new alpha-trifluoroethyl diazo reagent (HTFB) provide a great new tool for basic cellular studies facilitating the discovery of new drug candidates for human disease. Furthermore, we are interested in methodologies for beta-lactone synthesis and transformations. In this study, we demonstrated synthetic versatilities of beta-lactones for the synthesis of beta-lactam congeners of orlistat as fatty acid synthase inhibitors via SnCl4- promoted tandem Mukaiyama aldol-lactonization (TMAL) reaction and a one-pot, mild conversion of beta-lactones to beta-lactams. The inhibitory activities of the derived beta-lactam derivatives are determined in a biochemical fluorogenic assay using recombinant FASTE, and the micro-molar range FAS-TE inhibitory activities were observed. Additionally, we pursued synthetic studies toward the total synthesis of spongiolactone, which is a unique beta-lactone-containing marine diterpenoid, isolated from the marine sponge Spongionella gracilis. This natural product bears a unique tricyclic beta-lactone core possessing four contiguous stereogenic centers and an additional stereogenic quaternary carbon on a cyclohexyl appendage. We completed the total synthesis of 6,15-bis-epi-spongiolactone by employing an intramolecular nucleophilecatalyzed aldol-lactonization (NCAL) process as the key step to construct the fused tricyclic beta-lactone core. Importantly, we developed a double diastereoselective and, for the first time, a kinetic resolution via the NCAL process that enables an enantioselective strategy to the tricyclic beta-lactone core of (+)-spongiolactone. β-lactone β-lactam diazo reagent O-H insertion

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