1,022 research outputs found
Direct Access to β-Fluorinated Aldehydes by Nitrite-Modified Wacker Oxidation
An aldehyde-selective Wacker-type oxidation of allylic fluorides proceeds with a nitrite catalyst. The method represents a direct route to prepare β-fluorinated aldehydes. Allylic fluorides bearing a variety of functional groups are transformed in high yield and very high regioselectivity. Additionally, the unpurified aldehyde products serve as versatile intermediates, thus enabling access to a diverse array of fluorinated building blocks. Preliminary mechanistic investigations suggest that inductive effects have a strong influence on the rate and regioselectivity of the oxidation
Lewis base catalyzed reactions with latent nucleophiles and phosphonium intermediates
The aim of this thesis was to develop solutions to overcome the common problem related to nucleophile scope in Lewis base catalyzed reactions and develop new synthetic methods and generate new knowledge and deeper understanding of these processes. Relying on the strategies used in previous Lewis base catalyzed allylic substitutions using N-H acidic nucleophiles, we have expanded the scope to allylation of anilines that have been considered insufficiently N-H acidic for applications in such reactions. The concept of latent nucleophiles was the development of enantioselective N-allylation of N-silyl pyrroles, indoles and carbazoles using allylic luorides. They proceed with excellent regioselectivity and expand the scope of Lewis base catalyzed allylic substitutions to otherwise problematic nucleophiles. Further application of the concept of latent nucleophiles in Lewis base catalysis was pursued with C-centered nucleophiles for introduction of difluoromethyl phosphonate moiety. In contrast, the work presented in this thesis on reactions catalyzed by P-centered Lewis bases was focused on the possibility of simultaneous dual activation of small organic molecules with Lewis acids and Lewis bases that do not form stable Lewis adducts and constitute non-traditional frustrated Lewis pairs. The work on the development of 1,2-reduction of ynones and trans-hydroboration of ynoates highlighted the versatile reactivity of vinyl hosphonium salts and inspired further studies involving these types of intermediates. Interest in reactivity of vinyl phosphonium ions informed the interest in reactivity of aryl phosphonium ions. In this area, we have shown that thiazoles and benzothiazoles undergo regioselective C2-H functionalization to form thiazol-2-yltriphenylphosphonium salts which undergo efficient substitution reactions with N-, O-, S and Se-centered nucleophiles to introduce various heteroatom substituents in the C2 position of thiazoles and benzothiazole
Carbon(sp3)-fluorine bond-forming reductive elimination from palladium(IV) complexes.
The development of transition-metal-catalyzed reactions for the formation of CF bonds has been an area of intense research over the past decade.[1–3] Traditionally, the CF coupling step of these sequences has proven challenging because of the high kinetic barrier for CF bond-forming reductive elimination from most transition-metal centers.[1] Our approach to address this challenge has involved the use of PdII catalysts in conjunction with F+-based oxidants. Since 2006, a variety of PdII-catalyzed reactions of F+ reagents have been developed to introduce fluorine at both C(sp2 ) and C(sp3 ) centers.[4–6] These transformations have been proposed to proceed through CF bond-forming reductive elimination from transient, highly reactive PdIV alkyl/aryl fluoride intermediate
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Introduction of Fluorine and Fluorine-Containing Functional Groups
Over the past decade, the most significant, conceptual advances in the field of fluorination were enabled most prominently by organo- and transition-metal catalysis. The most challenging transformation remains the formation of the parent C[BOND]F bond, primarily as a consequence of the high hydration energy of fluoride, strong metal—fluorine bonds, and highly polarized bonds to fluorine. Most fluorination reactions still lack generality, predictability, and cost-efficiency. Despite all current limitations, modern fluorination methods have made fluorinated molecules more readily available than ever before and have begun to have an impact on research areas that do not require large amounts of material, such as drug discovery and positron emission tomography. This Review gives a brief summary of conventional fluorination reactions, including those reactions that introduce fluorinated functional groups, and focuses on modern developments in the field.Chemistry and Chemical Biolog
Palladium–mediated organofluorine chemistry
Producción CientíficaThe substitution of fluorine for hydrogen in a molecule may result in profound changes in its properties and behaviour. Fluorine does not introduce special steric constraints since the F atom has a small size. However, the changes in bond polarity and the possibility of forming hydrogen bonds with other hydrogen donor fragments in the same or other molecules, may change the solubility and physical properties of the fluorinated compound when compared to the non-fluorinated one. Fluorine forms strong bonds to other elements and this ensures a good chemical stability. Altogether, fluorinated compounds are very attractive in materials chemistry and in medicinal chemistry, where many biologically active molecules and pharmaceuticals do contain fluorine in their structure and this has been shown to be essential for their activityJunta de Castilla y León (programa de apoyo a proyectos de investigación – Ref. VA302U13)Junta de Castilla y León (programa de apoyo a proyectos de investigación – Ref. VA256U13
Recent developments in the Suzuki-Miyaura reaction: 2010-2014
The Suzuki-Miyaura reaction (SMR), involving the coupling of an organoboron reagent and an organic halide or pseudo-halide in the presence of a palladium or nickel catalyst and a base, has arguably become one of most utilized tools for the construction of a C-C bond. This review intends to be general account of all types of catalytic systems, new coupling partners and applications, including the literature between September 2010 and December 2014
Single and double stereoselective fluorination of (E)-allylsilanes
RIGHTS : This article is licensed under the BioMed Central licence at http://www.biomedcentral.com/about/license which is similar to the 'Creative Commons Attribution Licence'. In brief you may : copy, distribute, and display the work; make derivative works; or make commercial use of the work - under the following conditions: the original author must be given credit; for any reuse or distribution, it must be made clear to others what the license terms of this work are.Abstract Acyclic allylic monofluorides were prepared by electrophilic fluorination of branched (E)-allylsilanes with Selectfluor. These reactions proceeded with efficient transfer of chirality from the silylated to the fluorinated stereocentre. Upon double fluorination, an unsymmetrical ethyl syn-2,5-difluoroalk-3-enoic ester was prepared, the silyl group acting as an anti stereodirecting group for the two C-F bond forming events.Published versio
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C-F bond activation under transition-metal-free conditions
The unique properties of fluorine-containing organic compounds make fluorine substitution attractive for the development of pharmaceuticals and various specialty materials, which have inspired the evolution of diverse C-F bond activation techniques. Although many advances have been made in functionalizations of activated C-F bonds utilizing transition metal complexes, there are fewer approaches available for nonactivated C-F bonds due to the difficulty in oxidative addition of transition metals to the inert C-F bonds. In this regard, using Lewis acid to abstract the fluoride and light/radical initiator to generate the radical intermediate have emerged as powerful tools for activating those inert C-F bonds. Meanwhile, these transition-metal-free processes are greener, economical, and for the pharmaceutical industry, without heavy metal residues. This review provides an overview of recent C-F bond activations and functionalizations under transition-metal-free conditions. The key mechanisms involved are demonstrated and discussed in detail. Finally, a brief discussion on the existing limitations of this field and our perspective are presented
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Stereodivergent Construction of Tertiary Fluorides in Vicinal Stereogenic Pairs by Allylic Substitution with Iridium and Copper Catalysts.
Although much effort has been spent on the enantioselective synthesis of tertiary alkyl fluorides, the synthesis of compounds containing such a stereogenic center within an array of stereocenters, particularly two vicinal ones, remains a synthetic challenge, and no method to control the configuration of each stereogenic center independently has been reported. We describe a strategy to achieve such a stereodivergent synthesis of vicinal stereogenic centers, one containing a fluorine atom, by forming the connecting carbon-carbon bond with a catalyst system comprising an iridium complex that controls the configuration at the electrophilic carbon and a copper catalyst that controls the configuration at the nucleophilic fluorine-containing carbon. These reactions occur with alkyl- and aryl-substituted allylic esters and the unstabilized enolates of azaaryl ketones, esters, and amides in high yield, diastereoselectivity, and enantioselectivity (generally >90% yield, >20:1 dr, 97-99% ee). Access to all four stereoisomers of products demonstrates the precise control of the two configurations independently. This methodology extends to the stereodivergent construction of vicinal quaternary and tertiary stereocenters in similarly high yield and selectivity. DFT calculations uncover the origin of stereoselectivity of copper enolate in allylic substitution
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