Enantioselective synthesis reaction mechanisms

The potential of Fischer carbene complexes in the construction of complex structures from simple starting materials is nicely reflected in the next example. Thus, the reaction of alkenylcarbene complexes of chromium and tungsten with cyclopentanone and cyclohexanone enamines allows the di-astereo- and enantioselective synthesis of functionalised bicyclo[3.2.1]octane and bicyclo[3.3.1]nonane derivatives [12] (Scheme 44). The mechanism of this transformation is initiated by a 1,4-addition of the C -enamine to the alkenylcarbene complex. Further 1,2-addition of the of the newly formed enamine to the carbene carbon leads to a metalate intermediate which can... 

Soon thereafter, the Yamamoto group reported an extension of this work to the highly diastereo- and enantioselective synthesis of nitroso Diels-Alder-type bicycloketones using dienamines in the presence of the BINOL derivative 44 (Scheme 5.61) [115]. This reaction was thought to proceed through a sequential N-NA/ hetero-Michael reaction mechanism. Support for this mechanism was provided from an experiment employing bulkyl 4,4-diphenyl dienamine where the N-NA... 

Organometallic compounds asymmetric catalysis, 11, 255 chiral auxiliaries, 266 enantioselectivity, 255 see also specific compounds Organozinc chemistry, 260 amino alcohols, 261, 355 chirality amplification, 273 efficiency origins, 273 ligand acceleration, 260 molecular structures, 276 reaction mechanism, 269 transition state models, 264 turnover-limiting step, 271 Orthohydroxylation, naphthol, 230 Osmium, olefin dihydroxylation, 150 Oxametallacycle intermediates, 150, 152 Oxazaborolidines, 134 Oxazoline, 356 Oxidation amines, 155 olefins, 137, 150 reduction, 5 sulfides, 155 Oxidative addition, 5 amine isomerization, 111 hydrogen molecule, 16 Oxidative dimerization, chiral phenols, 287 Oximes, borane reduction, 135 Oxindole alkylation, 338 Oxiranes, enantioselective synthesis, 137, 289, 326, 333, 349, 361 Oxonium polymerization, 332 Oxo process, 162 Oxovanadium complexes, 220 Oxygenation, C—H bonds, 149... 

List gave the first examples of the proline-catalyzed direct asymmetric three-component Mannich reactions of ketones, aldehydes, and amines (Scheme 14) [35], This was the first organocatalytic asymmetric Mannich reaction. These reactions do not require enolate equivalents or preformed imine equivalent. Both a-substituted and a-unsubstituted aldehydes gave the corresponding p-amino ketones 40 in good to excellent yield and with enantiomeric excesses up to 91%. The aldol addition and condensation products were observed as side products in this reaction. The application of their reaction to the highly enantioselective synthesis of 1,2-amino alcohols was also presented [36]. A plausible mechanism of the proline-catalyzed three-component Mannich reaction is shown in Fig. 2. The ketone reacts with proline to give an enamine 41. In a second pre-equilib-... 

Di(carbene)gold(I) salts, oxidation, 2, 293—294 Dicarbido clusters, with decarutheniums, 6, 1036 Dicarbollide amides, with tantalum, 5, 184 Dicarbollide thorium complexes, synthesis and characterization, 4, 224—225 Dicarbollyl ligands, in nickel complexes, 8, 185 Dicarbonyl complexes arylation with lead triacetates diastereoselectivity, 9, 389 enantioselectivity, 9, 391 mechanisms, 9, 387 reaction examples, 9, 382 indium-mediated allylation, 9, 675 with iridium, 7, 287 reductive cyclization, 10, 529 in Ru and Os half-sandwiches, 6, 508 with Zr—Hf(II), 4, 700... 

It was soon recognized that in specific cases of asymmetric synthesis the relation between the ee of a chiral auxiliary and the ee of the product can deviate from linearity [17,18,72 - 74]. These so-called nonlinear effects (NLE) in asymmetric synthesis, in which the achievable eeprod becomes higher than the eeaux> represent chiral amplification while the opposite case represents chiral depletion. A variety of NLE have been found in asymmetric syntheses involving the interaction between organometallic compounds and chiral ligands to form enantioselective catalysts [74]. NLE reflect the complexity of the reaction mechanism involved and are usually caused by the association between chiral molecules during the course of the reaction. This leads to the formation of diastereoisomeric species (e.g., homochiral and heterochiral dimers) with possibly different relative quantities due to distinct kinetics of formation and thermodynamic stabilities, and also because of different catalytic activities. 

The application of molecular mechanics to enantio- and diastereo-selective synthesis is less straight-forward, and publications in this area have only started to appear recently. In the case of the racemate separations described above, the isomer abundances of equilibrated solutions are taken to be related to the energy of all local minima. In contrast, in order to predict the enantiomeric excesses arising from chiral syntheses, the reaction mechanisms and the structures of relevant intermediates or transition states have to be known since their relative energies need to be calculated in order to predict the enantiomeric excesses. Thus, it is to be expected that quantum-mechanical methods such as DFT, in conjunction with molecular mechanics will provide the best insights into enantioselectivity[2391 (see also Section 2.2). 

Especially the latter subject is a strongly developing field of research, trying to find answers to such important questions as, e.g., the stereo- and enantioselective synthesis of organosilicon polymer precursors and the use of Si-M compounds for the production of new polymers. In addition, even in widely used industrial processes as, e.g. the hydrosilylation reaction, the respective mechanism is still under discussion and research is focused on the development of more active and less expensive catalysts (compared to the today used nobel metal complexes). 

These studies on catalytic hydrogenation using chirally modified catalysts suggest that enantioselective hydrogenation is still an open area for the study of asymmetric synthesis, especially as a practical synthetic method for chiral nonracemic organic compounds. However, catalytic hydrogenation is affected by so many variables that it is not easy to optimize the stereoselectivity. Many physicochemical studies have been made to elucidate the reaction mechanism, and these have been reviewed by Tai. ... 

Reaction Mechanism and Enantioselectivity of Lipases 278 Lipase-catalyzed Synthesis and Polymerization of Optically Pure Monomers 280... 

The Wittig reaction has been used to construct the side-chain in a synthesis of (-)-sirenin (208), a water mold sperm-attacking hormone.ii The intermediate (206) was generated, without competing formation of the structural isomer (207), by reaction of the ylide (205) with (204) under salt-free conditions in DME. Standard Wittig methods have been used to construct the side-chain in an enantioselective synthesis of (+)-(7 , 9Z)-methyl trisporate (209) and its (9E)-isomer.l 12 The reaction of triphenyl-(vinylimino)phosphorane derivatives (210) with tropones provides a convenient synthesis of 1-aza-azulenes (211) and (212) in either one or two steps (Scheme 28).H The mechanism of the one-step reaction was investigated using deuterium-labelled tropane derivatives. 

The asymmetric dihydroxylation of olefins by 0s04 NR3 catalysts is an extremely useful reaction in organic synthesis. It is able to introduce two vicinal functional groups simultaneously on olefins not functionahsed. The apphca-tion of theoretical methods to study this reaction has proven to be critical in order to determine the reaction mechanism, and to identify the origin of the enantioselectivity. 

The first example of direct enantioselective addition of a C—H bond to a ketone was reported by Shibata and co-workers in 2009 using the cationic Ir/ (S)-Hg-BINAP as the catalyst in the synthesis of a chiral 4-acetyl-3-hydroxy-3-methyl-2-oxindole with 72% ee. Recently, Yamamoto and co-workers developed a cationic Ir/(R,R)-Me-BIPAM catalyzed asymmetric intramolecular direct hydroarylation of a-keto amides 178 affording the chiral 3-substi-tuted 3-hydroxy-2-oxindoles 179 in high yields with complete regioselectivity and high enantioselectivity (84-98% ee). In their proposed reaction mechanism, the aryl iridium complex formed via C—H bond activation is coordinated with the two carbonyl groups of the amide (Scheme 5.65). 

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