Spelling suggestions: "subject:"electrophilic""
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Electrophilic substitution of aromatic compoundsAhmed, Siddique January 1972 (has links)
No description available.
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Kinetics of the addition of halogens to olefines : a study of the addition of bromine to olefines in aqueous solutionPring, M. January 1965 (has links)
No description available.
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Synthesis and characterization of benzodithiophene- and quinoxalinedithienothiophene-based semiconducting materials for organic solar cellsHuang, Lanqi 25 March 2019 (has links)
Organic semiconducting materials have been attracted considerable attention as a promising technology for the next generation flexible electronic devices, such as solar cells and field-effect transistors because of their advantages of low-cost, structural versatility and flexibility. Many organic semiconducting materials have been developed in recent years. In this thesis, four pi-conjugated building blocks based on benzodithiophene and quinoxalinedithienothiophene were applied to develop novel photovoltaic materials, including donor-acceptor alternating copolymers as a donor material for polymer solar cells, photosensitizers for dye sensitized solar cells, small molecule hole transporting materials for perovskite solar cells and small molecule acceptors for organic solar cells. A comprehensive review of current development of organic photovoltaic materials was presented in Chapter 1. In Chapter 2, a series of D-A copolymers (PBB-n) based on 4,7-di(thiophen-2-yl)benzo[c][1,2,5]thiadiazole and 4,5-bis((2-ethylhexyl)oxy)benzo[2,1-b:3,4-b'] dithiophene attached with different solubilizing side-chains were designed, synthesised and characterized. In general, PBB-n polymers showed good absorption in the region of visible light and UV region, indicating such polymers are a promising light harvester. Also, PBB-n exhibited suitable energy levels, suggesting that they could be applied as the donor materials in polymer solar cells. PBB-n also exhibited various extent of aggregation behaviour. Chapter 3 described syntheses and the fluorination effect of two series of fluoro-substituted PBB-n copolymers, namely PfBB-n and PffBB-n on optical, electrochemical, and optoelectronic properties. Among them, PfBB-n series was characterized with photovoltaic performance. The champion devices fabricated from PfBB-12 showed a PCE as high as 9.7%, with a Voc of 0.92 V, a Jsc of 16.60 mA/cm-2 and a FF of 63.49%. Cells fabricated from other PfBB-n copolymers also exhibited good PV performance with PCE ranging from 7.4 - 8.5%. For PffBB-n polymers, temperature-dependent aggregation behaviour was exploited by modulating the coating temperature during device fabrication. PSC devices based on PffBB-n exhibited good PV performance with PCE ranging from 7.4% to 9.9%. Among which, PffBB-14 provided the most promising PV performance with PCE of 9.9%, a Voc of 0.92 V, a Jsc of 16.8 mA/cm-2 and a FF of 64.36%. Electron deficient conjugated structure was seldom used as the π-bridge in metal-free photosensitizers. In Chapter 4, four novel organic photosensitizers, namely QC5-m and PC5-n were designed with an electron deficient π-bridge. Typical sandwich-structured DSSCs based on the newly developed photosensitizers exhibited promising photovoltaic performance with PCE ranging from 5.23 - 7.77 %, with a maximum Jsc as high as 15.63 mA cm-2. These results suggest that the use of electron deficient π-bridge provides alternative approach to construct efficient organic photosensitizers. Chapter 5 and Chapter 6 described the design, synthesis and investigation of novel hole-transporting materials and electron acceptor materials based on benzo[2,1-b:3,4-b']dithiophene-4,5-dione derived building blocks as potential organic photovoltaic materials for solar cell applications. Keywords: organic photovoltaic materials, photosensitizers, polymer solar cell, electron acceptor, hole-transporting materials.
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Engaging Esters as Cross-Coupling ElectrophilesBen Halima, Taoufik 09 August 2019 (has links)
Cross-coupling reactions, where a transition metal catalyst facilitates the formation of a new carbon-carbon or carbon-heteroatom bond between two coupling partners, has become one of the most widely used, reliable, and robust family of transformations for the construction of molecules. The Nobel Prize was awarded to pioneers in this field who primarily used aryl iodides, bromides, and triflates as electrophilic coupling partners. The expansion of the reaction scope to non-traditional electrophiles is an ongoing challenge to enable an even greater number of useful products to be made from simple starting materials. The major goal of this thesis research is to improve and expand upon this field by using esters as electrophiles via the activation of the strong C(acyl)−O bond. Esters are particularly robust in comparison to other carboxylic acid derivatives used in cross-coupling reactions. Success on the activation of such inert functional group using catalysis has both fundamental and practical value. By discovering new reaction modes of this abundant functional group, synthetic routes to access novel or industrially important molecules can be improved.
Chapter 1 of this thesis describes a literature overview of what has been accomplished in the field of cross coupling reactions using carboxylic acid derivatives as electrophilic coupling partners.
Chapter 2 discloses the first palladium Suzuki-Miyaura couplings of phenyl esters to produce ketones. The method is efficient and robust, giving good yields of useful products. The reaction is proposed to proceed via an oxidative addition to the strong C(acyl)−O bond of the ester. In contrast to previous efforts in this field that use traditional catalysts such as Pd(PPh3)4, the developed reaction requires use of an electron-rich, bulky N-heterocyclic carbene ligand, which facilitates the strong bond activation.
Furthermore, a palladium-catalyzed cross-coupling between aryl esters and anilines is reported, enabling access to diverse amides. The reaction takes place via a similar activation of the C−O bond by oxidative addition with a Pd−NHC complex, which enables the use of relatively non-nucleophilic anilines that otherwise require stoichiometric activation with strong bases to react.
Chapter 3 discloses a nickel-catalyzed amide bond formation using unactivated and abundant esters. In this transformation, an accessible nickel catalyst can facilitate the activation of diverse aliphatic and aromatic esters to enable direct amide bond formation with amines as nucleophiles. No stoichiometric base, acid, or other activating agent is needed, providing exceptional functional group tolerance and producing only methanol as a by-product. This reaction is of both fundamental and practical importance because it is the first to demonstrate that simple conditions can enable Ni to cleave the C–O bond of an ester to make an oxidative addition product, which can be subsequently coupled with amines. This discovery contrasts industrially-common and wasteful methods that still require stoichiometric activating agents or multistep synthesis.
Chapter 4 describes the evaluation of different types of cross-coupling reactions using methyl esters as electrophilic coupling partner. A high-throughput screening technique has been applied to this project. A combination between specific ligands, known by their efficiency to activate strong C−O bonds, and literature-based conditions has been designed for the chosen transformations. Using this strategy, two promising hits have been obtained using the same NHC ligand: a decarbonylative Suzuki-Miyaura and a decarbonylative borylation reaction.
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Synthèse de tropyliums fonctionnalisés et de quinoxalines à partie d'électrophiles fluorés / Synthesis of fonctionalised tropyliums and quinoxalines from fluorinated electrophilesJovene, Cyril 09 June 2015 (has links)
Les benzofuroxanes sont des hétérocycles possédant des propriétés biologiques importantes. Ce type de composés possède une forte électrophilie en fonction du nombre de groupements électroattracteurs présent sur leur carbocycle. Les travaux de recherche de cette thèse s’inscrivent dans la continuité des travaux reportés dans ce domaine. Ainsi, dans une première partie purement bibliographique, sera développé l’historique de la synthèse et de la réactivité des benzofuroxanes ainsi que les travaux du laboratoire.Dans une seconde partie est présenté le développement de voies de synthèses originales vers des fluoronitrobenzofuroxanes à partir de composés simples et variés de type phénols, anisoles, et anilines. La synthèse de composés benzofuroxanes polyfluorés est ensuite présentée, revisitant la formation du 4,6-difluorobenzofuroxane qui a permis de mettre en évidence des résultats erronés de la littérature et de proposer une nouvelle méthode efficace pour sa formation. L’utilisation de la RMN à température variable a permis de déterminer sans ambiguïtés la structure de ces benzofuroxanes fluorés.Dans une troisième partie, leur réactivité est étudiée selon plusieurs méthodes, de la réactivité péricyclique à des calculs théoriques d’électrophilie globale en passant par des potentiels de réduction mesurés par voie électrochimique. Ces résultats sont comparés à d’autres électrophiles comme le trinitrobenzène en série aromatique ou le DNBF, pour les molécules superélectrophiles. De plus, la formation de quinoxalines possédant potentiellement des activités biologiques sera décrite.Dans une quatrième partie, la synthèse de composés de type benzodifuroxanes est développée. Après une introduction sur leurs caractéristiques structurales, la synthèse du 4-fluorobenzodifuroxane est décrite ainsi que la formation des analogues bromé et iodé. D’autre part la synthèse du 4-méthoxybenzodifuroxane et du 4-aminobenzodifuroxane sera décrite permettant d’apporter des informations sur la réactivité de ce type de composés.Enfin dans un dernier chapitre, la réactivité d’un électrophile chargé tel que le tropylium vis-à-vis de nucléophiles faibles indoliques sera présentée. La réaction de couplage avec le tropylium permettra de mettre en valeur la régiosélectivité de ce couplage. Les tropylidènes obtenus seront caractérisés afin de mettre en avant les caractéristiques spectrales de ce type d’adduit. Les tropylidènes formés sont ensuite oxydés afin de conduire à des tropyliums fonctionnalisés très colorés qui peuvent être aussi obtenus en une seule étape.Finalement, cette thèse s’achèvera sur une conclusion générale qui présentera aussi les perspectives sur le sujet et ce que ces travaux ont apporté à la chimie des benzofuroxanes. / Benzofuroxans are heterocycles exhibiting many biological activities. This kind of compounds has been shown to be very electrophilic spieces when substituted by electron-withdrawing groups. This work is an important part of the works reported in this field of heterocyclic chemistry. In the first part of this PhD thesis, one will find the bibliographic part dedicated to benzofuroxans including the works of our team.In a second part, the development of original synthetic pathways leading to fluoronitrobenzofuroxans from simple compounds like phenols, anisoles or anilines is shown. The synthesis of polyfluorinated benzofuroxans will be presented by revisiting the formation of 4,6-difluorobenzofuroxan highlighting erroneous published results and allowing the finding of new and efficient methods leading to the difluorinated benzofuroxan. The use of variable temperature NMR experiments allows the unambiguous determination of the structure of fluorinated benzofuroxans.In a third part the reactivity of benzofuroxans is studied using different methods such as the experimental study of the pericyclic Diels-Alder reaction, theoretical calculations of global electrophilcity and the electrochemical measurements of reduction potentials. These results are compared to those of other electrophiles like trinitrobenzene in the usual aromatic series and of 4,6-dinitrobenzofuroxan in the superelectrophilic dimension. Then, the formation of quinoxalines exhibiting potential biological activities will be described.In a fourth part the synthesis of benzodifuroxan-type compounds is developed. After an introduction dealing with their main structural features, the synthesis of the 4-fluorobenzodifuroxan and the formation of brominated and iodinated analogs are described. Then the synthesis of the 4-methoxybenzodifuroxan and the 4-aminobenzodifuroxan will bring interesting informations on the reactivity of this kind of compounds.In a last chapter the reactivity of the tropylium cation with weak nucleophiles such as indoles will be presented. The C-C coupling reactions with the tropylium cation allow the isolation of many tropylidenes moieties, which will be subsequently oxidized to lead to highly functionalized and colored substituted tropyliums.Finally, a general conclusion will summarize the significant results and the perspectives of this work in the field of benzofuroxans chemistry
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Mechanistically-Guided Development of Electroreductive, Cross-Electrophile Coupling Reactions of Challenging ElectrophilesHamby, Taylor B. January 2022 (has links)
No description available.
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Investigations of Novel Mechanisms of Action for Anti-Bacterial and Anti-Cancer Agent DevelopmentVerghese, Jenson 01 May 2014 (has links)
The development of drugs and therapeutic agents for combating infections and human malignancies continues to be a forefront area in both academic and industrial research. This is driven by the rapid emergence of multi-drug resistant bacterial strains and accumulating mutations in cancer targets that is quickly rendering our current arsenal of drugs ineffective for these therapies. Unless new drugs with novel mechanisms of action are identified and developed at a faster pace, we face a losing battle in managing these diseases. The first part of this work concerns with the natural product Simocyclinone D8 (SD8). Simocyclinone D8 is an angucyclinone antibiotic that inhibits DNA gyrase with a novel mechanism of action that has been termed competitive inhibition. Simocyclinone D8 was found to inhibit the growth of both Gram-(+ve) and Gram-(–ve) organisms and also inhibit a fluoroquinolone resistant mutant of DNA gyrase. Inspired by the structure and novel mechanism of action that SD8 displays, we synthesized analogues based on the co-crystal structure of SD8 with DNA gyrase. These compounds were found to inhibit DNA gyrase, albeit by a different mechanism of action than that of SD8. We also conducted studies towards the total chemical synthesis of SD8 and made three out of the four fragments in SD8 in decent yields. The second part of this work is focused on the development of a substrate-competitive covalent inhibitor for protein kinase B (AKT). AKT is a valid target for cancer research with two compounds currently in late stage clinical trials. Developing substrate- competitive inhibitors for kinases is a novel approach in targeting them, with very few examples in the literature. This mechanism has been postulated to overcome common resistance mutations that cancer targets harbor. A major drawback in this approach is the low binding affinity for peptide substrates by kinases. We circumvented this problem of affinity by utilizing a covalent mode of binding and synthesized a potent non-peptide active-site directed irreversible compound that inhibits AKT. Further studies on this compound are underway and are expected to yield a compound that can be used as a therapeutic agent or as a probe for AKT.
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Sustainable Strategies for Site-Selective C−VC Bond Formations through Direct C−H Bond Functionalizations / Nachhaltige Strategien zur Selektiven C−VC Bindungsknüpfung durch C−H BindungsfunktionalisierungFenner, Sabine 25 January 2012 (has links)
No description available.
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Ubiquitin-phosphonamidates and -phosphonothiolates for DUB targeting and protein ubiquitinationSchwagerus, Sergej 18 January 2022 (has links)
Im ersten Teil dieser Arbeit wurde die Staudinger-Phosphonit-Reaktion auf Azidohomoalanin-haltiges Ubiquitin angewendet, um ortsspezifisch modifizierte Alkinphosphonamidat-Ubiquitine zu erzeugen. Diese Ubiquitin-basierten Sonden wurden bei neutralem pH-Wert in selektiven Konjugationen mit DUBs, die ein Cystein im aktiven Zentrum beinhalten, eingesetzt, auch in Anwesenheit anderer Thiole. Dabei beobachteten wir DUB-Spezifitäten in Abhängigkeit von der Phosphonamidat-Position innerhalb der Sonde. Die DUB-Selektivität konnte auch an Pull-Down-Experimenten aus Zelllysaten gezeigt werden. Zusätzlich konnte die Cystein-Selektivität der Sonde an ausgewählten konjugierten DUBs mittels MS/MS-Analyse nachgewiesen werden. Wir beobachteten auch unterschiedliche Ausmaße der DUB-Inhibition bei der Inkubation mit den verschiedenen Phosphonamidat-Sonden. Im Hinblick auf das DUB-Targeting in lebenden Zellen untersuchten wir auch Bedingungen für zellpenetrierende Peptid-konjugierte Ubiquitine für einen Transport der Sonde in das Zytosol der Zellen.
Im zweiten Teil der Arbeit haben wir die neuartige, chemisch induzierte Phosphonothiolat Elektrophile für Thiol-Konjugation angewendet, um unhydrolysierbare ubiquitinierte Substrate herzustellen. Es gelang uns, ein hoch elektrophiles Ubiquitin-Vinylphosphonothiolat mit guter Ausbeute zu erzeugen. Wir konnten die frisch hergestellte Sonde in Konjugationen mit Cysteinen an ausgewählten Proteinen einsetzen. Um unser Konzept zu etablieren, generierten wir ein monoubiquitiniertes α-Synuclein und demonstrierten dessen strukturelle Integrität in einer enzymatischen Ubiquitinierung des Konjugats. Außerdem stellten wir ein künstlich K48-verknüpftes Diubiquitin her, das von spezifischen Antikörpern ähnlich erkannt wurde wie das native K48-verknüpfte Diubiquitin, aber in Gegenwart von DUBs sich als stabil erwies. Das Ubiquitin-Vinylphosphonothiolat zeigte ebenfalls eine selektive DUB-Konjugation, wenn nur kurze Inkubationszeiten verwendet wurden. / In the first part of this thesis a Staudinger-phosphonite reaction was applied on azidohomoalanine-containing ubiquitin to generate site-specifically modified alkynephosphonamidate ubiquitins. These ubiquitin-based probes were utilized in selective conjugations of active site cysteine-containing DUBs at neutral pH, even in the presence of other thiols. Furthermore, we observed DUB specificities depending on the phosphonamidate position within the probe. The selectivity could also be demonstrated in pull-down experiments from cell lysates. Moreover, the probe’s cysteine selectivity within chosen conjugated DUBs could be determined using MS/MS analysis. Consequently, we observed varying extents of DUB inhibition upon incubation with the different phosphonamidate probes. For DUB targeting in living cells we also investigated conditions of cell penetrating peptide conjugated ubiquitin in order to successfully deliver them to the cytosol.
In the second part of this thesis, we applied the novel chemically induced phosphonothiolate electrophiles for thiol conjugation to produce unhydrolyzable ubiquitinated substrates. Starting from a disulfide-activated cysteine ubiquitin mutant, we managed to generate a highly electrophilic ubiquitin vinylphosphonothiolate in satisfactory yield. We could apply the freshly prepared probe in conjugations with cysteines on selected proteins, in which the conjugation product showed to be remarkably stable. To establish our concept, we prepared monoubiquitinated α-synuclein and demonstrated its structural integrity in the performance of an enzymatical ubiquitination of the conjugate. Furthermore, we produced an artificially K48-linked diubiquitin, which was similarly recognized by specific antibodies as the native K48-linked diubiquitin and was not hydrolyzed in the presence of DUBs. The ubiquitin vinylphosphonothiolate displayed also selective DUB conjugation, when only short incubations were used.
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