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1	Synthesis and Characterization of (Phospine)- and (N-Heterocyclic Carbene)Gold(I) Halides, Azides, Alkynyls, Triazoles, and Dendrimers and the Synthesis and Characterization of Gold(I) Thiacrown Macrocycles Robilotto, Thomas J. January 2011 (has links) No description available. Chemistry gold azide gold(I) triazole gold(I) alkynyl thiacrown macrocycle phosphine N-heterocyclic carbene apoptosis
2	Gold(I) and Platinum(II)-Catalyzed Hydrofunctionalization of Allenes and Alkenes with Carbon and Nitrogen Nucleophiles Butler, Kristina LeAnne January 2012 (has links) <p><p>The wide-spread occurrence of biologically active nitrogen-containing heterocycles and allylic amines inspired us to develop atom-economical methods for their syntheses.</p></p><p><p>A cationic gold(I) <italic>N</italic>-heterocyclic carbene complex catalyzed the intermolecular hydroarylation of allenes with indoles to form (<italic>E</italic>)-allylic indoles in modest to good yield at room temperature. The protocol was effective for monosubstituted, 1,3-disubstituted, and tetrasubstituted allenes and various indoles.</p> </p><p><p>Platinum(II) bis(phosphine) complexes catalyzed the intermolecular hydroamination of monosubstituted allenes with secondary alkylamines in good yield with selective formation of (<italic>E</italic>)-allylic amines. The scope of the protocol included aryl and alkyl monosubstituted allenes as well as a variety of both cyclic and acyclic secondary alkylamines.</p></p><p><p>The scope of gold(I)-catalyzed intermolecular hydroamination of 1-alkenes with 1-methyl-2-imidazolidinone was expanded to include additional 1-alkenes functionalized with carboxylic acid derivatives. However, a nucleophile screen failed to identify nucleophiles other than cyclic ureas and 2-oxazolidinone that efficiently undergo hydroamination with 1-alkenes. Various carbamates, arylamines, amide derivatives, sulfur-containing amide derivatives, and α-heteroatom compounds failed to react with 1-octene under gold(I)-catalyzed conditions.</p></p><p><p>A chiral bis(gold) phosphine complex catalyzed the stereoconvergent, intermolecular enantioselective hydroamination of chiral, racemic 1,3-disubstituted allenes with carbamates to form <italic>N</italic>-allylic carbamates in good to high yield with up to 92% <italic>ee</italic>. In addition, enantiopurity experiments suggested the nature of the catalytically active species changes with increasing concentration of <italic>N</italic>-allylic carbamate.</p></p> / Dissertation Chemistry allene gold(I) hydroamination hydroarylation platinum(II)
3	Design and Synthesis of Gold (I) Acyclic Diamino Carbene Complexes as Metallodrugs for Cancer and for Asymmetric Catalysis Asuramana Pedi Durayalage, Roshani 07 1900 (has links) Many previous studies have demonstrated that gold compounds possess successful results in catalysis and in medicinal chemistry. The central aim of this dissertation is the design and synthesis of novel gold (I) acyclic diamino carbene complexes as a chemotherapeutic agent for triple-negative breast cancer (TNBC) and for catalysis. In this study, a series of chiral neutral and cationic gold (I) acyclic diamino carbene (ADC) complexes and neutral gold (I) bis- ADC complexes have been synthesized. As the chiral neutral gold (I) ADCs, four diastereomers of S binaphthyl L proline tertiary butyl ester gold (I) chloride, S binaphthyl D proline tertiary butyl ester gold (I) chloride, R binaphthyl L proline tertiary butyl ester gold (I) chloride, and R binaphthyl D proline tertiary butyl ester gold (I) chloride have been synthesized and characterized. Different chiral gold (I) ADC complexes with bulky chiral binaphthyl group and with different amine groups of morpholine, chiral proline methyl ester, and benzyl ester have been synthesized and characterized. After that four diastereomers of the nitrile adduct of cationic binaphthyl proline tertiary butyl ester nitrile and four diastereomers of the isonitrile versions of it have been synthesized and characterized. A series of gold (I) cationic bis ADC complexes have been synthesized and characterized. All these novel gold ADC complexes were tested for biological activity against TNBC cell line MDA-MB-231 and cationic S binaphthyl D proline ester isonitrile adduct, S binaphthyl D proline ester isonitrile adduct and R binaphthyl D proline ester isonitrile adduct gave promising inhibition rates. According to Lipinski's rule, lipophilicity determines the effectiveness of the drug absorption to the body through the lipid membrane. To determine the drug-likeness of the gold ADC complexes, log P values were calculated for some of the synthesized complexes using a modified shake flask method. Gold (I) ADC complexes have been renowned for their ability in catalysis, but enantioselective catalysis is not that well studied. A3 coupling reaction is a well-known reaction for the synthesis of propargyl amines. Here, A3 coupling reaction with a chiral amine has been performed using the previously synthesized four diastereomers of binaphthyl proline tertial butyl ester gold (I) ADCs (SL, RD, RL, SD) as the catalyst expecting four different diastereomers of the product. The reaction exhibited reasonable yields but with a low enantiomeric excess (ee%). However, it gave proof of the principle that asymmetric induction is possible with the synthesized novel chiral gold (I) ADC complexes. metallodrugs chiral gold(I) acyclic diamino carbenes triple-negative breast cancer lipophilicity asymmetric catalysis A3 coupling Chemistry, Inorganic Chemistry, Pharmaceutical Chemistry, General
4	Gold(I)-Catalyzed Dehydrative Amination and Etherification of Allylic Alcohols Mukherjee, Paramita January 2012 (has links) <p>Allylic amines are important and fundamental building blocks due to their wide-spread occurrence in many natural products and the ability to further functionalize them by transformations on the double bond to generate a diverse range of compounds. Transition-metal catalyzed allylic substitution represents an attractive and efficient approach towards the synthesis of these allylic amines. However, limitations associated with the traditional methods developed for such allylic amination in terms of regiospecificity, atom economy and generality in these transformations, combined with the importance of allylic amination, prompted us to develop novel atom efficient and regiospecific methods for their synthesis.</p><p>A 1:1 mixture of AuCl[P(<italic>t</italic>-Bu)<sub>2</sub><italic>o</italic>-biphenyl] (5 mol %) and AgSbF<sub>6</sub> (5 mol %) catalyzed the intermolecular amination of underivatized allylic alcohols with 1-methyl-2-imidazolidinone and related nucleophiles. The first examples of intermolecular allylic amination was developed that in the case of gamma-unsubstituted and gamma-methyl-substituted allylic alcohols, occurred with high gamma-regioselectivity and <italic>syn</italic>-stereoselectivity.</p><p>A 1:1 mixture of AuCl[P(<italic>t</italic>-Bu)<sub>2</sub><italic>o</italic>-biphenyl] (5 mol %) and AgSbF<sub>6</sub> (5 mol %) also served as a very efficient catalytic system for the intramolecular amination of allylic alcohols with alkylamines to form substituted pyrrolidine and piperidine derivatives. The protocol was effective for a range of secondary as well as primary alkylamines as nucleophiles with different substitutions on the alkyl chain tethering the nucleophile to the allylic alcohol. The method was also extended towards the total synthesis of the naturally occurring alkaloid (S)-(+)-coniine in two steps from the starting (R,Z)-8-(N-benzylamino)-3-octen-2-ol. In addition, gold(I)-catalyzed cyclization of (R,Z)-8-(N-benzylamino)-3-octen-2-ol (96% ee) led to isolation of (R,E)-1-benzyl-2-(1-propenyl)piperidine in 99% yield and 96% ee that established the net syn-addition of the nucleophile with respect to the departing hydroxyl group.</p><p> A bis(gold) phosphine complex (S)-Au<sub>2</sub>Cl<sub>2</sub>(DTBM-MeOBIPHEP) (2.5 mol %) and AgClO<sub>4</sub> (5 mol %) catalyzed the intramolecular enantioselective dehydrative amination of allylic alcohols with carbamates to form the corresponding substituted pyrrolidines, piperidines, morpholines and piperazines in excellent yields and with up to 95% ee. This general and effective protocol tolerated a range of carbamates as well as sulfonamides as nucleophiles. Cyclization of chiral amino allylic alcohols that possessed a stereogenic homoallylic or hydroxy-bound carbon atom occurred with an overriding catalyst control of asymmetric induction. In addition, stereochemical analysis of the cyclization of a chiral non-racemic secondary allylic alcohol established the net syn-displacement of the hydroxy group by the carbamate nucleophile.</p><p>Alongside allylic amination, a cationic gold(I)-N-heteocyclic carbene complex catalyzed the intermolecular etherification (alkoxylation) of allylic alcohols in a regiospecific and syn-stereoselective fashion. The transformation was highly efficient to utilize unactivated primary and secondary alcohols as nucleophiles with different allylic alcohols to undergo regiospecific etherification. Employment of a chiral nonracemic secondary allylic alcohol, trans-5-(benzyloxy)pent-3-en-2-ol (98% ee) showed a high level of chirality transfer on reaction with n-butanol to the corresponding allylic ether, (2-butoxypent-3-en-1-yloxy)methylbenzene (97% ee) and established the net syn-addition of the alcohol nucleophile with respect to the departing hydroxyl group of the allylic alcohol.</p> / Dissertation Chemistry Allylic Alcohols Asymmetric Catalysis Dehydrative Amination Dehydrative Etherification Gold(I)-Catalysis
5	Method Development for the Stereoselective Synthesis of Medium-Sized Cyclic Ethers and Application to Natural Product Synthesis: Part I. Organocatalytic Oxa-Conjugate Addition for α,αÂ´-trans-Oxepanes Part II. Gold(I)-Catalyzed Alkoxylation for α,αÂ´-cis-Oxocenes Part III. Studies toward the Synthesis Lanier, Megan January 2015 (has links) <p>Medium-sized cyclic ethers are challenging synthetic targets due to enthalpic and entropic barriers. Methods for the stereoselective synthesis of α,α΄-disubstituted medium-sized cyclic ethers began to appear with the discovery of naturally-occurring, ladder-shaped polycyclic ethers, such as brevetoxin B, and monocyclic ethers, such as (+)-laurencin. Despite the progress made in this field, limitations remain including competing formation of smaller ring sizes and scarcity of catalytic methods. Our aim has been to develop stereoselective syntheses for 7- and 8-membered cyclic ethers which have potential for application in natural product synthesis. The C-O bond disconnection was selected for the methods described within because cyclization and stereoinduction could be achieved simultaneously. In the case of 7-membered cyclic ethers, an organocatalytic oxa-conjugate addition reaction promoted by the gem-disubstituent (Thorpe−Ingold) effect has been developed to stereoselectively provide α,α′-trans-oxepanes. A gold(I)-catalyzed alkoxylation reaction has also allowed access to α,α′-cis-oxocenes. This method has been probed for feasibility in the stereoselective synthesis of (+)-intricenyne, an 8-membered cyclic ether belonging to the C15 nonterpenoid acetogenin natural product class. These methods have the potential to become general and efficient routes to highly functionalized oxepanes and oxocenes.</p> / Dissertation Organic chemistry cyclic ether gold(I)-alkoxylation intricenyne organocatalyzed oxa-conjugate addition oxepane oxocene
6	Metal-NHC complexes for anti-cancer applications : gold(I) for antimitochondrial activity and iridium(III) for photodynamic therapy / Complexes métalliques à ligands NHC pour des applications anticancer : or(I) pour l'activité antimitochondriale et iridium(III) pour la thérapie photodynamique Zhang, Chen 26 September 2018 (has links) Dans ce travail de thèse, plusieurs groupes de nouveaux complexes d'or(I) à base de carbènes N-hétérocyclique (NHC)contenant des bras amino-aliphatiques et aromatiques avec un potentiel intéressant dans des applications biomédicales ont été synthétisés et entièrement caractérisés. En outre, une série de complexes d'iridium(III) contenant des ligands NHC avec des activités anticancéreuses prononcées pour une application en thérapie photodynamique, a étépréparée et entièrement caractérisée. Le premier groupe représente une famille de complexes cationiques or(I) bis(NHC) contenant des bras latéraux amino-aliphatiques. Ces complexes ont étésynthétisés et étudiés pour leurs activités antiprolifératives vis-à-vis de quatre lignées cellulaires cancéreuses humaines et de la lignée cellulaire non cancéreuse MDCK. Dans cette série, la lipophilie est directement liée àl'activitécytotoxique contre les cellules cancéreuses. La deuxième famille de composés concerne les complexes cationiques or(I) bis(NHC) contenant des bras latéraux amino-aromatiques. La cytotoxicitéin vitro de ces complexes et de leurs proligands sur les lignées cellulaires représentatives du cancer de la prostate PC-3 et de la vessie T24 a étéévaluée. Tous ces complexes présentent des valeurs de Log P (lipophilie) supérieures àcelles de la première série de complexes en accord avec leur cytotoxicité plus élevée, mais une lipophilie trop élevée peut également conduire àune sélectivitéplus faible. Afin de développer un candidat-médicament avec une activitéet une sélectivité optimisées, nous avons conçu et synthétisé la troisième famille de complexes cationiques or(I) bis(NHC). Les valeurs de log P de cette série se situent entre la première série et la deuxième série. Ces complexes moins lipophiles sont moins cytotoxiques envers les lignées cellulaires saines (NIH3T3) et montre des activités anticancéreuses un peu plus faibles sur les cellules PC-3 que la deuxième série, avec néanmoins des valeurs de GI50 dans la gamme du nanomolaire. Les études mécanistiques sur deux complexes d'or(I) ont été réalisées. Les mesures d'absorption cellulaire ont montré une accumulation cellulaire rapide et une bonne biodisponibilitédes complexes, en accord avec l'activitéantiproliférative de ces deux complexes. De plus, les deux complexes inhibent la thiorédoxine reductase (TrxR), une cible commune pour les complexes d'or(I). La mort cellulaire induite par ces deux complexes est dépendante des espèces réactives de l'oxygène. En plus des activités anticancéreuses, nous avons également testédes complexes d'or(I) mono-NHC pour une autre application biomédicale, la leishmaniose, maladie parsitaire. Ils ont été testés in vitro sur les formes promastigotes et amastigotes axéniques de L. infantum. De plus, leur cytotoxicitéa étéévaluée sur les macrophages murins J774A.1 afin de déterminer leur sélectivitéd'action. Un autre sujet de cette thèse concerne les complexes d'iridium(III)-NHC. Trois familles de complexes ont étépréparées et caractérisées. La cytotoxicitéin vitro de tous les complexes sur les cellules cancéreuses de la prostate PC-3 et de la vessie T24, et les cellules non cancéreuses NIH3T3 a étéévaluée. De plus, tous les complexes sont des agents théranostiques, et les expériences de microscopie confocale d'un complexe ont montréqu'il pouvait être rapidement et efficacement absorbédans les cellules PC-3 et se localiser spécifiquement dans les mitochondries. De manière intéressante, ces complexes peuvent agir comme des photosensibilisateurs efficaces. La cytotoxicitéde ces complexes a étéaugmentée substantiellement après une irradiation lumineuse de 365 nm, ce qui suggère le potentiel élevéde ces agents anticancéreux théranostiques ciblant les mitochondries pour la thérapie photodynamique. / In this work of thesis, several groups of novel NHC-based gold(I) complexes containing aliphatic and aromatic amino-side arms with interesting potential in biomedical applications have been synthesized and fully characterized. Also, a series of iridium(III) complexes containing NHC ligands with pronounced PDT anticancer activities has been prepared and fully characterized. The first group represents a family of cationic bis(NHC)-gold(I) complexes containing aliphatic amino-side arms. These complexes have been synthesized and investigated for their antiproliferative activities towards four human cancer cell lines and the non-cancerous MDCK cell line. In this series, the lipophilicity correlates directly with the cytotoxic activity against cancer cells. The second family of compounds concerns cationic gold(I) bis(NHC) complexes containing aromatic amino-side arms. The in vitro cytotoxicity of these complexes and proligands on the representative PC-3 prostate and T24 bladder cancer cell lines has been evaluated. All these complexes show higher Log P values (lipophilicity) than the first series of complexes, and in line with this higher cytotoxicity, nevertheless too high lipophilicity can also lead to lower selectivity. In order to develop a drug candidate with optimized activity and selectivity, we designed and synthesized the third family of cationic gold(I) bis(NHC) complexes. The Log P values of this series were between the first series and the second series. The lower cytotoxicity towards non-cancerous NIH3T3 cells was found for this series of complexes whereas they also displayed less activities towards cancer cells than the second series. The mechanistic studies on two gold complexes by monitoring the cellular uptake showed the rapid cellular accumulation of the intact gold bis(NHC) and a good bioavailability, in good agreement with the antiproliferative activity of these two complexes. Moreover, both complexes inhibit TrxR, a common target for gold(I) complexes. The cell death induced by these two complexes was ROS-dependent. Besides anticancer activities, we also tested gold(I) mono-NHC complexes for other biomedical applications in parasite disease Leishmaniasis. They were screened in vitro against both promastigote and axenic amastigote forms of L. infantum. Moreover, their cytotoxicity was evaluated on the murine J774A.1 macrophages in order to determine their selectivity of action. Another topic of this thesis concerns iridium(III)-NHC complexes. Three families of theranostic iridium(III)-NHC complexes were prepared and characterized. The in vitro cytotoxicity of all the complexes against PC-3 prostate, T24 bladder cancer cells and non-cancerous NIH3T3 cells was evaluated. Moreover, all complexes are theranostic agents, and the confocal microscopy experiments of one complex showed that it can be quickly and effectively taken up into PC-3 cells and specifically localize into mitochondria. Interestingly, these complexes can act as efficient photosensitizers. The cytotoxicity of these complexes was increased substantially upon 365 nm light irradiation, which suggested the high potential to be mitochondria-targeting theranostic anticancer agents for photodynamic therapy. Or(I) Iridium(III) NHC Anticancer Thérapie photodynamique Lipophilie Gold(I) NHC Anticancer Photodynamic therapy Lipophilicity
7	Gold (i)-catalyzed Retro-Cyclopropanation Reaction and Development of Trindane-Based Approach Toward c60 Solorio Alvarado, César Rogelio 27 October 2011 (has links) La cicloisomerización de 1,5-, 1,6- y 1,7-eninos catalizada por Au(I) y Au(III) ha sido desarrollada con un enfoque sintético y mecanístico. Los aportes hechos hasta el momento nos han permitido elucidar de modo general la reactividad de los complejos catiónicos de oro(I) (Esquema R1). Se demostró que en la ciclación de 1,6-eninos B1, la migración propargílica 1,5 del éter metílico tenía lugar originando la estructura base de los globuloles, una familia de productos naturales. Sin embargo al explorar la reactividad de 1,7- eninos C1, tuvo lugar una migración propargílica 1,6, dando lugar a la formación de benzo[C]fluorenos. Alternativamente con una sustitución similar en los eninos de partida utilizando los 1,6-eninos D1 (esquema R2) tuvo lugar una nueva reacción catalizada por oro. En este caso, un nuevo proceso de anulación catalizado por complejos catiónicos de oro(I) nos condujo a la formación de naftalenos 1,3-disustituidos E1 (esquema R2) Los naftalenos 1,3-disustituidos son una clase de compuestos no accesibles de manera convencional mediante acoplamiento cruzado o por sustitución electrófila aromática. Durante el estudio de anulación con D1, determinamos el mecanismo de esta reacción. Encontramos que este proceso tiene lugar vía cicloisomerización 6- endo-dig generando un dihidronaftaleno D2 (esquema R2), que tras migración [1,2] de hidógeno genera D3. Tras protodemetalación, genera el enol eter D4. Retro-ciclopropanación sobre D4 origina un naftaleno 1,3-bisustituido E1, junto con la formación de un carbeno libre de oro(I) G1 para dar lugar a un bisciclopropano tetracíclico F1. Esta es la primera vez que se observa el proceso de reto-ciclopropanación en química de oro. Gold (I) catalyzed Retro-cylopropanation Trindane-based fullerene synthesis 542 547
8	Gold(I)-Catalyzed Enantioselective Hydroamination of Unactivated Alkenes Lee, seong du January 2012 (has links) <p>Numerous methodologies for efficient formation of carbon-nitrogen bonds have been developed over the decades due to the widespread importance of nitrogen containing compounds in pharmaceuticals and bulk commercial chemicals. Among many methods, hydroamination, especially, has attracted enormous attention because of its atom-economical characteristic to synthesize amine moieties. As a result, numerous publications have been reported relating the hydroamination reaction using various metal catalysts. However, the hydroamination of unactivated alkenes still remains a challenge task because of the low reactivity of the CC double bond. Recent development of superior gold(I) catalysis in many organic transformations stimulated us to develop efficient gold(I)-catalyzed methods for enantioselective intra- and intermolecular hydroamination of unactivated alkenes. </p><p>A gold(I)-catalyzed system for enantioselective intramolecular hydroamination of unactivated alkenes has been developed. For the effective gold(I)-catalyzed method, various gold(I)-catalysts have been synthesized and tested. Among the catalysts, bis(gold) complexes containing an axially chiral bis(phosphine) ligand catalyze the enantioselective intramolecular hydroamination of unactivated alkenes with carboxamide derivatives, most effectively. The method was effective for both carbamates and ureas to form pyrrolidine derivatives with up to 85 % ee.</p><p>The first enantioselective intermolecular hydroamination of unactivated alkenes was realized by a gold(I)-catalyzed method. The gold(I) catalyst system adds cyclic ureas to unactivated 1-alkenes to produce corresponding enantiomerically enriched hydroamination product in good yield with enantioselectivity up to 78 % ee. </p><p>Polymer-embedded ligands have been synthesized to demonstrate proofs of concepts for fluxional mechanocatalysis. We applied a certain shear stress using a rheometer in the course of palladium-catalyzed asymmetric allylic alkylation to examine catalytic reactivity change under the mechanical force.</p> / Dissertation Chemistry Organic chemistry Inorganic chemistry Asymmetric synthesis Enantioselective hydroamination Gold(I) catalysis organometallic chemistry unactivated alkenes
9	Ligand Effects in Gold(I) Acyclic Diaminocarbene Complexes and Their Influence on Regio- and Enantioselectivity of Homogeneous Gold(I) Catalysis Ellison, Matthew Christopher 08 1900 (has links) This dissertation focuses on the computational investigation of gold(I) acyclic diaminocarbene (ADC) complexes and their application in homogeneous gold(I) catalysis. Chapter 2 is an in-depth computational investigation of the σ- and π-bonding interactions that make up the gold-carbene bond. Due to the inherent conformation flexibility of ADC ligands, distortions of the carbene plane can arise that disrupt orbital overlap between the lone pairs on the adjacent nitrogen atoms and the empty p-orbital of the carbene. This study investigated the affect these distortions have on the strength of the σ- and π-bonding interactions. This investigation demonstrated that while these distortions can affect the σ- and π-bonding interactions, the ADC ligand have to become highly distorted before any significant change in energy of either the σ- or π-bonding interactions occurs. Chapter 3 is a collaborative investigation between experimental and computational methods, DFT calculations were employed to support the experimental catalytic results and determine the role that steric effects have in controlling the regioselectivity of a long-standing electronically controlled gold(I)-catalyzed tandem 1,6-enyne cyclization/hydroarylation reaction with indole. This study demonstrated that by sterically hindering nucleophilic attack of indole at the favored position, nucleophilic attack would occur at a secondary position leading to the selective formation of the electronically unfavored product. Chapter 4 is a collaborative investigation between experimental and computational methods. DFT calculations were employed to investigate and rationalize the importance of secondary non-covalent interactions and their influence on the enantioselectivity of a gold(I)-catalyzed intramolecular hydroamination of allene reaction. Through computational investigation of the enantiodetermining step, and the non-covalent interactions present between 2′-aryl substituent and the rest of the catalyst, it was determined that the presence of CF3 group on the 3,5-position of the 2′-aryl ring is crucial to maintaining a more rigid chiral pocket leading to higher enantiomeric excesses in this dynamic system. This increased rigidity is believed to be attributable to the several weak non-covalent interactions that arise between the allene substrate or diisopropyl N-substituent and the fluorine atoms of the CF3 groups. Gold(I) Catalysis Acyclic Diaminocarbenes DFT Organometallic Chemistry Computational Chemistry Chemistry, Inorganic
10	Silver(I) and Gold(I) N-Heterocyclic Carbene Complexes Durmus, Semih January 2006 (has links) No description available. Chemistry, Inorganic NHCs CARBENES SILVER(I) NHC GOLD(I) NHC ANTIMICROBIALS ANTICANCER HISTAMINE HISTIDINE UROCANIC ACID

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