Reactions asymmetric amination

The l ,J -DBFOX/Ph-transition metal aqua complex catalysts should be suitable for the further applications to conjugate addition reactions of carbon nucleophiles [90-92]. What we challenged is the double activation method as a new methodology of catalyzed asymmetric reactions. Therein donor and acceptor molecules are both activated by achiral Lewis amines and chiral Lewis acids, respectively the chiral Lewis acid catalysts used in this reaction are J ,J -DBFOX/Ph-transition metal aqua complexes. 

Perhaps the most successful industrial process for the synthesis of menthol is employed by the Takasago Corporation in Japan.4 The elegant Takasago Process uses a most effective catalytic asymmetric reaction - the (S)-BINAP-Rh(i)-catalyzed asymmetric isomerization of an allylic amine to an enamine - and furnishes approximately 30% of the annual world supply of menthol. The asymmetric isomerization of an allylic amine is one of a large and growing number of catalytic asymmetric processes. Collectively, these catalytic asymmetric reactions have dramatically increased the power and scope of organic synthesis. Indeed, the discovery that certain chiral transition metal catalysts can dictate the stereo-... 

The strategy for the asymmetric reductive acylation of ketones was extended to ketoximes (Scheme 9). The asymmetric reactions of ketoximes were performed with CALB and Pd/C in the presence of hydrogen, diisopropylethylamine, and ethyl acetate in toluene at 60° C for 5 days (Table 20) In comparison to the direct DKR of amines, the yields of chiral amides increased significantly. Diisopropylethylamine was responsible for the increase in yields. However, the major factor would be the slow generation of amines, which maintains the amine concentration low enough to suppress side reactions including the reductive aminafion. Disappointingly, this process is limited to benzylic amines. Additionally, low turnover frequencies also need to be overcome. 

The Schiff bases being derivatives of aldehydes or ketones and various amines have received considerable attention because of their interesting physical and chemical properties, involvement in biologically important reactions and widespread application of their metal complexes. Increasing interest in optically active Schiff bases is connected with the discovery at the beginning of the 1990s of the so-called Jacobsen catalysts used in several asymmetric reactions showing excellent enantioselectivity. 

Asymmetric reactions have also been developed. The reactions of allyltitaniums with chiral aldimines derived from optically active 1-phenylethylamine afford optically active homoallylic amines with excellent diastereofacial selectivities. Thus, the Cram syn addition products are obtained highly predominantly when using crotyltitanium reagent 33, as exemplified in Scheme 13.30 [61]. 

Muller has explored enantioselective C-H insertion using optically active rhodium complexes, NsN=IPh as the oxidant, and indane 7 as a test substrate (Scheme 17.8) [35]. Chiral rhodium catalysts have been described by several groups and enjoy extensive application for asymmetric reactions with diazoalkanes ]46—48]. In C-H amination experiments, Pirrung s binaphthyl phosphate-derived rhodium system was found to afford the highest enantiomeric excess (31%) of the product sulfonamide 8 (20equiv indane 7, 71% yield). 

Recently, M. Asami and T. Mukaiyama 124) synthesized ot-benzyloxyaldehydes (109) having a chiral tertiary center at the ot-carbon atom in high enantiomeric excess by successive treatment of the aminal (102) with diisobutylaluminium hydride (DIBAL-H) and Grignard reagents. The asymmetric reaction is applied to the total synthesis of exo-(+)-brevicomin (110), the principal aggregation pheromone in the frass of the female western pine beetle (Dendroctonus brevicomis). 

It is true that highly enantioselective reactions are possible with proline in the asymmetric a-amination of aldehydes by azodicarboxylates and in a-oxidation with nitrosobenzene. However, good rather than excellent yields and enantioselectivities are more common in intermolecular Michael and aldol reactions. Moreover, the high catalyst loadings required for proline-catalyzed aldol reactions (up to 30%), and low TOFs (from hours to days to achieve a good conversion, even at a high catalyst... 

Apart from these well-known catalysts, much effort has been expended in the synthesis and applications of chiral phase-transfer catalysts that include various quaternary ammonium salts, metal-salen complexes, phosphonium salts, and chiral amines. However, few of these catalysts have shown promising levels of asymmetric induction in asymmetric reactions. 

In this chapter, we will outline the application of organocatalysis for the enantio-selective a-heteroatom functionalization of mainly aldehydes and ketones. Attention will be focused on enantioselective animation-, oxygenation-, fluorination-, chlorination-, bromination-, and sulfenylation reactions catalyzed by chiral amines. The scope, potential and application of these organocatalytic asymmetric reactions will be presented as the optically active products obtained are of significant importance, for example in the life-science industries. 

A basic amine catalyst may promote the self-aldol reaction of the aldehyde, having an enolizable carbonyl. This reaction can be particularly important in the case of slowly reacting hindered aldehydes. In order to avoid this secondary reaction, a number of trialkylphosphines were tested and, in non-asymmetric reactions, tributylphosphine was generally found to be the most effective [32, 33],... 

Asymmetric organocatalytic Morita-Baylis-Hillman reactions offer synthetically viable alternatives to metal-complex-mediated reactions. The reaction is best mediated with a combination of nucleophilic tertiary amine/phosphine catalysts, and mild Bronsted acid co-catalysts usually, bifunctional chiral catalysts having both nucleophilic Lewis base and Bronsted acid site were seen to be the most efficient. Although many important factors governing the reactions were identified, our present understanding of the basic factors, and the control of reactivity and selectivity remains incomplete. Whilst substrate dependency is still considered to be an important issue, an increasing number of transformations are reaching the standards of current asymmetric reactions. 

Enantioselective reactions have also been reported for the hydrolysis of enamines containing a chiral amine moiety via protonation or of prochiral enamines by the use of a chiral acid. Other asymmetric reactions are summarized in an excellent review by Seebach and coworkers179 and by Oare and Heathcock193. 

The previous examples are selected asymmetric reductive animations of ketones to give chiral, a-branched amines (Eq. 32) however, the corresponding reactions of aldehydes are unknown. We reasoned that such a process might be realized if enolizable, a-branched aldehydes are used. Their asymmetric reductive amination should give -branched amines via an enantiomer-differentiating kinetic resolution (Eq. 33). 

List B (2000) The direct catalytic asymmetric three-component Mannich reaction. J Am Chem Soc 122 9336-9337 ListB (2001) Asymmetric aminocatalysis. Synlett 2001 1675-1686 List B (2002a) Direct catalytic asymmetric alpha-amination of aldehydes. J Am Chem Soc 124 5656-5657... 

Asymmetric electrophilic amination reactions using silyl ketene acetals 1 and di-tert-butyl azodicarboxylate (DBAD) finally lead to a-hydrazino 3 and ( )-a-amino acids 415. 

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