Deprotonation, asymmetric

The lithium amide of (,S S)-(1) has been used to convert racemic a-substituted ketones into optically active ketones via sequential deprotonation/asymmetric protonation of rigid prochiral enolates. Enantiomeric enrichment may occur during the protonation step as a result of the tight coordination between the enolate and the lithium amide in the form of diastereomeric complexes (eq 7). ... 

Keywords Phase transfer. Chiral ligand. Chiral base, Allylic alkylation. Cinchonine, Enolate alkylation. Asymmetric deprotonation. Asymmetric arylation. Radical alkylation... 

Keywords. Configurational stability, a-Hetero carbanion, Enantioselective reaction. Asymmetric deprotonation. Asymmetric substitution... 

Dimethyl-tert-butylphosphine sulphide was deprotonated asymmetrically at a methyl group in the presence of ( )-sparteine to afford a P-stereogenic product in a subsequent alkylation step (Scheme 38). ... 

Among the most successful classes of asymmetric acyl anion equivalents are the dioxane-containing a-amino nitriles 99 introduced by Enders and coworkers. These are deprotonated by EDA, and the resulting anions act as efficient equivalents of RCO for addition to a, (3-unsaturated esters [90AG(E)179],... 

Oxathiane 101 is readily deprotonated using s-BuLi, and the resulting anion reacts with alkyl halides, ketones, and benzonitrile (85JOC657). The majority of work in this area, however, is due to Eliel and coworkers and has involved chiral 1,3-oxathianes as asymmetric acyl anion equivalents. In the earliest work it was demonstrated that the oxathianes 102 and 103, obtained in enantiomeri-cally pure form by a sequence involving resolution, could be deprotonated with butyllithium and added to benzaldehyde. The products were formed with poor selectivity at the new stereocenter, however, and oxidation followed by addition... 

Asymmetric induction by sulfoxide is a very attractive feature. Enantiomerically pure cyclic a-sulfonimidoyl carbanions have been prepared (98S919) through base-catalyzed cyclization of the corresponding tosyloxyalkylsulfoximine 87 to 88 followed by deprotonation with BuLi. The alkylation with Mel or BuBr affords the diastereomerically pure sulfoximine 89, showing that the attack of the electrophile at the anionic C-atom occurs, preferentially, from the side of the sulfoximine O-atom independently from the substituent at Ca-carbon. The reaction of cuprates 90 with cyclic a,p-unsaturated ketones 91 was studied but very low asymmetric induction was observed in 92. 

Asymmetric Michael addition of chiral enolates to nltroalkenes provides a useful method for the preparation of biologically important compotmds. The Michael addition of doubly deprotonated, optically active fi-hydroxycarboxylates to nltroalkenes proceeds v/ith high dias-tereoselecdvity to give fityr/iro-hydroxynitroesters fEq, 4,58, ... 

The first attempt at a catalytic asymmetric sulfur ylide epoxidation was by Fur-ukawa s group [5]. The catalytic cycle was formed by initial alkylation of a sulfide (14), followed by deprotonation of the sulfonium salt 15 to form an ylide 16 and... 

A-Acido imines (R R"C = N —X=0) like /V-acyl (X = CR) /V-sulfonyl [X = S(R)=0]2-7 or /V-diphenylphosphinoylimines [X = P(C6H5)2]3 are masked inline derivatives of ammonia. Compared to the imines themselves these activated derivatives are better electrophiles showing less tendency to undergo undesired deprotonation rather than addition of organometal-lics1812 The apparent advantages of these compounds have been exploited for asymmetric syntheses of amines, amides, amino acids and /J-lactams1-8 I6. 

An excellent synthetic method for asymmetric C—C-bond formation which gives consistently high enantioselectivity has been developed using azaenolates based on chiral hydrazones. (S)-or (/ )-2-(methoxymethyl)-1 -pyrrolidinamine (SAMP or RAMP) are chiral hydrazines, easily prepared from proline, which on reaction with various aldehydes and ketones yield optically active hydrazones. After the asymmetric 1,4-addition to a Michael acceptor, the chiral auxiliary is removed by ozonolysis to restore the ketone or aldehyde functionality. The enolates are normally prepared by deprotonation with lithium diisopropylamide. 

The imines of ( )-(l/ ,2/ ,5/ )-2-hydroxy-3-pinanone and glycine, alanine and norvaline methyl esters were highly successful as Michael donors in the asymmetric synthesis of 2,3-di-substituted glutamates. The chiral azaallyl anions derived from these imines by deprotonation with lithium diisopropylamide in THF at — 80 "C undergo addition to various ,/ -unsaturated esters with modest to high diastereoselectivities210,394. 

In the asymmetric version of the [1,2] -aWittig rearrangement (see Sect. 3.2), the deprotonation of S-methyl (ferf-butyl)arylphosphinothioate 103 followed by alkylation affords the corresponding (alkylthiomethyl)phosphine oxides 104 together with over-reacted products 105 (no diastereomeric excess is observed for this compound) and 106 [67] (Scheme 30). 

Herrmann et al. reported for the first time in 1996 the use of chiral NHC complexes in asymmetric hydrosilylation [12]. An achiral version of this reaction with diaminocarbene rhodium complexes was previously reported by Lappert et al. in 1984 [40]. The Rh(I) complexes 53a-b were obtained in 71-79% yield by reaction of the free chiral carbene with 0.5 equiv of [Rh(cod)Cl]2 in THF (Scheme 30). The carbene was not isolated but generated in solution by deprotonation of the corresponding imidazolium salt by sodium hydride in liquid ammonia and THF at - 33 °C. The rhodium complexes 53 are stable in air both as a solid and in solution, and their thermal stability is also remarkable. The hydrosilylation of acetophenone in the presence of 1% mol of catalyst 53b gave almost quantitative conversions and optical inductions up to 32%. These complexes are active in hydrosilylation without an induction period even at low temperatures (- 34 °C). The optical induction is clearly temperature-dependent it decreases at higher temperatures. No significant solvent dependence could be observed. In spite of moderate ee values, this first report on asymmetric hydrosilylation demonstrated the advantage of such rhodium carbene complexes in terms of stability. No dissociation of the ligand was observed in the course of the reaction. 

Even if organocatalysis is a common activation process in biological transformations, this concept has only recently been developed for chemical applications. During the last decade, achiral ureas and thioureas have been used in allylation reactions [146], the Bayhs-Hillman reaction [147] and the Claisen rearrangement [148]. Chiral organocatalysis can be achieved with optically active ureas and thioureas for asymmetric C - C bond-forming reactions such as the Strecker reaction (Sect. 5.1), Mannich reactions (Sect. 5.2), phosphorylation reactions (Sect. 5.3), Michael reactions (Sect. 5.4) and Diels-Alder cyclisations (Sect. 5.6). Finally, deprotonated chiral thioureas were used as chiral bases (Sect. 5.7). 

Asymmetric deprotonation of prochiral cychc ketones (Scheme 50) was performed with chiral ureas in the presence of butylhthium. Yields were good (85-88%) with high enantioselectivities (83-87%). Moderate enantioselectiv-ity is obtained with the cyclopentyl-containing urea (Scheme 50 37% ee with R = Ph 7% ee with R = Me) [ 168,169]. 

Improvement in the catalyst activities and enantioselectivities was realised by the development of the chiral, bidentate alkoxy-functionalised imidazolium and imidazolidinium pro-ligands (134 and 136). 134, after deprotonation, was used to prepare the well-defined complex 135. Both 136 in the presence of BuLi and Cu(OTf)2 or 135 without any additional co-reagents were efficient catalysts in the asymmetric 1,4 addition of dialky Izincs and Grignards to cyclohexen-2-one giving higher ee (83% at rt and 51% at -30°C, respectively) [107, 108]. 

Addition of such a-lithiosulfinyl carbanions to aldehydes could proceed with asymmetric induction at the newly formed carbinol functionality. One study of this process, including variation of solvent, reaction temperature, base used for deprotonation, structure of aldehyde, and various metal salts additives (e.g., MgBrj, AlMej, ZnClj, Cul), has shown only about 20-25% asymmetric induction (equation 22) . Another study, however, has been much more successful Solladie and Moine obtain the highly diastereocontrolled aldol-type condensation as shown in equation 23, in which dias-tereomer 24 is the only observed product, isolated in 75% yield This intermediate is then transformed stereospecifically via a sulfoxide-assisted intramolecular 8, 2 process into formylchromene 25, which is a valuable chiron precursor to enantiomerically pure a-Tocopherol (Vitamin E, 26). 

Several stress tests were performed before scale-up. If the asymmetric deprotonation of 19 was carried out at -55 to -45 °C instead of-70 to -60 °C, product 5 from the coupling reaction was obtained in a significantly lower 85% ee although the yield was not affected (83%). An overcharge of (-)-sparteine provided only a marginal improvement in the ee of product 5 for example, l.lequiv of sparteine provided a 93% ee while 0.90 equiv of sparteine gave a slightly eroded 89% ee. 

The consistent observation of the arylated products with 92% ee confirms that the enantioselectivity of the asymmetric deprotonation was preserved during the transmetalation with ZnCl2 and retained during the Pd-catalyzed coupling. In fact, the Negishi coupling with 3-bromopyridine (entry 16) was performed at 60 °C, and still provided 26m in 92% ee, which constitutes a formal total synthesis of (R)-nicotine [27]. 

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