Amines aldol reaction, chiral auxiliary

Since most often the selective formation of just one stereoisomer is desired, it is of great importance to develop highly selective methods. For example the second step, the aldol reaction, can be carried out in the presence of a chiral auxiliary—e.g. a chiral base—to yield a product with high enantiomeric excess. This has been demonstrated for example for the reaction of 2-methylcyclopenta-1,3-dione with methyl vinyl ketone in the presence of a chiral amine or a-amino acid. By using either enantiomer of the amino acid proline—i.e. (S)-(-)-proline or (/ )-(+)-proline—as chiral auxiliary, either enantiomer of the annulation product 7a-methyl-5,6,7,7a-tetrahydroindan-l,5-dione could be obtained with high enantiomeric excess. a-Substituted ketones, e.g. 2-methylcyclohexanone 9, usually add with the higher substituted a-carbon to the Michael acceptor ... 

Chiral imines derived from 1-phenylethanone and (I. Sj-exo-l, 7,7-trimethyIbicyclo-[2.2.1]heptan-2-amine [(S)-isobornylamine], (.S>1-phenylethanamine or (R)-l-(1-naphthyl) ethanamine are transformed into the corresponding (vinylamino)dichloroboranes (e.g., 3) by treatment with trichloroborane and triethylamine in dichloromethane. Reaction of the chiral boron azaenolates with aromatic aldehydes at 25 "C, and subsequent acidic hydrolysis, furnishes aldol adducts with enantiomeric excesses in the range of 2.5 to 47.7%. Significantly lower asymmetric inductions are obtained from additions of the corresponding lithium and magnesium azaenolates. Best results arc achieved using (.S )-isobornylamine as the chiral auxiliary 3. 

Some enantiomerically pure substituted 2-oxazolidinones are excellent as chiral auxiliaries. From the pioneering studies 2 conducted in the early 1980 s of the uses of such auxiliaries has emerged what is perhaps the most widely used method today for the preparation of enantiomerically highly enriched a-alkylalkanoic acids, alcohols and aldehydes, that is, the alkylation of enolates from chiral 3-acylated 2-oxazolidinones followed by auxiliary removal2 59. The early work has been reviewed60-62. These enantiomerically pure cyclic imide auxiliaries have been used not only for alkylations but also in a plethora of a-functionalization reactions, such as diastereoselective aldol, a-hydroxylation, a-amination and Diels-Alder reactions and these are discussed elsewhere in this volume. 

An alternate approach comprises replacing the pendant sugar by either a carbo-cyclic or a heterocyclic ring. The enantioselective synthesis starts by formation of the imide (45-3) by reaction of the aion from the chiral auxiliary (45-2), derived from S-phenylalaninol and the pentene ester (45-1). Treatment of the product with triethyl amine and the trifalate from dibutylboronic acid leads to the transient enol borate (45-4). Aldol addition of that enol to acrolein proceeds stereospecifically to the alcohol (45-5) due to the transfer of chirality from the chiral auxiliary. 

The examples outlined in this chapter show that carbohydrates are efficient stereodifferentiating auxiliaries, which offer possibilities for stereochemical discrimination in a wide variety of chemical reactions. Interesting chiral products are accessible, including chiral carbo- and heterocycles, a- and 3-amino acid derivatives, 3-lactams, branched carbonyl compounds and amines. Owing to the immense material published since the time of the earlier review articles on carbohydrates in asymmetric synthesis [9,10], the examples discussed in this chapter necessarily focused on the use of carbohydrates as auxiliaries covalently linked to and cleavable from the substrate. Given the scope of this chapter, a discussion of other interesting asymmetric reactions has not been permitted — for example, reactions in which carbohydrate-derived Lewis acids, such as cyclopentadienyl titanium carbohydrate complexes, exhibit stereocontrol in aldol reactions [180]. Similarly, processes in which in situ glycosylation induces reactivity and stereodifferentiation — for example, in Mannich reactions of imines [181] — have also been excluded from this discussion. 

The preferred auxiliaries in chemistry at NSC Technologies are oxazolidinones. Oxazolidinones have found widespread use as chiral auxiliaries. A wide range of reactions is available and well documented [5], including aldol alkylations oc-substitution with a heteroatom such as halogenation, aminations, hydroxyla-tions, and sulphenylations Diels-Alder cycloadditions and conjugate additions. 

Asymmetric aldolization of a-isocyanoacetamide and fluorinated benzaldehydes has been realized with a gold(I) salt and a ferrocenyl amine-phosphine ligand. (Salen)-Ti complexes serve well in catalyzing the condensation of diketene with aldehydes. " A camphor lactam is an adequate chiral auxiliary as its derived imide undergoes asymmetric aldol reactions. 

Enantiomerically pure oxazolines and oxazolidinones have found widespread application in organic synthesis as chiral auxiliaries. They have been mainly used for the synthesis of enantiomerically pure amino acids but also as chiral auxiliaries to produce non-racemic enolates as pioneered by Evans.The reaction types proceeding with high stereocontrol include enolate alkylation, enolate oxidation, enolate halogenation, enolate amination, enolate acylation, aldol reaction and Diels-Alder reactions. 

An asymmetric intramolecular Michael-aldol reaction which leads to nonracemic tricyclic cyclobutanes is performed by using TMSOTf andbis[(/ )-l-phenylethyl]amine as chiral amine, but only moderate enantioselectivities are reached (eq 68). A similar reaction sequence can also be carried out with TMSOTf and HMDS as base, with (—)-8-phenylmenthol as the chiral auxiliary however, the iodotrimethylsilane-HMDS system is more efficient in terms of yield and diastereoselectivity. The combination EtsN/TMSOTf (or some other trialkylsilyl triflates) has been used to accomplish an intramolecular Michael reaction, which was the key step for the synthesis of sesquiterpene (=E)-ricciocarpin A. ... 

It is interesting that the condensation between electron-rich phenol, amine, and a chiral a -A, A -dibenzylamino aldehyde has been reported to be temperature sensitive, with high syn selectivity at high reaction temperatures while high anti selectivity is observed at low reaction temperatures. Similar to the Aldol Condensation, the Mannich reaction can be promoted or catalyzed by either acid or base. Furthermore, different protic acids or Lewis acid alone or in combination with a different chiral ligand or auxiliary group is used to enhance the stereoselectivity of the Mannich reaction, such as proline, (,S )-amino sulfonamide, BINOL phosphate," At-spiro chiral quaternary ammonium bromide, and dodecylbenzenesulfonic acid" as well as Lewis acids, such as Cu(OAc)2, CuC104, " Cu(OTf)2-chiral diamine complexes,... 

Chiral imidazolidin-4-ones-chiral secondary amines-had already been successfully used in asymmetric synthesis before they started their own career as organo-catalysts [1]. They were deployed as chiral auxiliaries for alkylation processes [2], Michael additions [3], and aldol reactions [4], For syntheses of this class of catalyst see Reference [5]. The ability to activate both carbonyl compounds by enamine formation as well a, 3-unsaturated carbonyl compounds by intermediate formation of iminium ions makes imidazolidin-4-ones a valuable class of organocatalysts in both series. Thus, they can roughly be divided by their mode of activation into enamine [6] or iminium [7] catalysis (Scheme 4.1). These catalysts were successfully deployed in a wide range of several important enantioselective C-C bond formation and functionalization processes. Figure 4.1 shows the chiral imidazo-lidinones covered in this chapter. 

Evans has pioneered the use of carboximide-derived enolates in diastereo-selective enolate alkylation reactions [15, 82]. As discussed in subsequent chapters, N-acyl oxazolidinones (such as 114, 115, and 116) enjoy a unique position in asymmetric synthesis as chiral auxiliaries with wide applications in numerous mechanistically unrelated asymmetric transformations, among them aldol (Chapter 4), Diels-Alder (Chapter 17), enolate amination (Chapter 10), and conjugate addition (Chapter 12) reactions. Oxazolidinones 114 and 115 generally lead to Ca-substituted carboximide products in one dia-stereomeric series (cf 119, dr>99 1), while the complementary diastereo-meric adducts such as 122 dr =98 2) can be accessed through the use of oxazolidinone 116 (Scheme 3.18) [82]. 

One of the most attractive options for asymmetric aldol reactions available to the synthetic chemist is to use enolates of carboxylic acid derivatives (inter alia ester, amide, or imide) with an appended chiral auxiliary (alcohol, amine, urethane). An early example of this approach dates back to 1938, when McKenzie reported that benzaldehyde undergoes addition by (-)-menthyl malonate (42) to give propanoic acid derivative 43 in 21 % ee (Equation 4) [43]. The modest selectivity was attributed to the conformational flexibility of ester enolates (cf. 44). 

The enantioselective aldol and Michael additions of achiral enolates with achiral nitroolefins and achiral aldehydes, in the presence of chiral lithium amides and amines, was recently reviewed354. The amides and amines are auxiliary molecules which are released on work-up (equation 90 shows an example of such a reaction). 

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