Enantiomerically pure preparation

Although unsynunetrically substituted amines are chiral, the configuration is not stable because of rapid inversion at nitrogen. The activation energy for pyramidal inversion at phosphorus is much higher than at nitrogen, and many optically active phosphines have been prepared. The barrier to inversion is usually in the range of 30-3S kcal/mol so that enantiomerically pure phosphines are stable at room temperature but racemize by inversion at elevated tempeiatuies. Asymmetrically substituted tetracoordinate phosphorus compounds such as phosphonium salts and phosphine oxides are also chiral. Scheme 2.1 includes some examples of chiral phosphorus compounds. 

Chiral chemical reagents can react with prochiral centers in achiral substances to give partially or completely enantiomerically pure product. An example of such processes is the preparation of enantiomerically enriched sulfoxides from achiral sulfides with the use of chiral oxidant. The reagent must preferential react with one of the two prochiral faces of the sulfide, that is, the enantiotopic electron pairs. 

Compound A can be prepared in enantiomerically pure form. It is racemized by heating to 120°C with an of about 30kcal/mol. Suggest a mechanism for the racemization process. 

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. 

Although very efficient, the broad application of the direct preparation is restricted due to the limited number of pure starting enantiomers. The design of a multistep process that includes asymmetric synthesis is cumbersome and the development costs may be quite high. This approach is likely best suited for the multi-ton scale production of commodity enantiomers such as the drugs ibuprofen, naproxen, atenolol, and albuterol. However, even the best asymmetric syntheses do not lead to products in an enantiomerically pure state (100 % enantiomeric excess). Typically, the product is enriched to a certain degree with one enantiomer. Therefore, an additional purification step may be needed to achieve the required enantiopurity. 

In the next step, the best candidate from the series 2-oxo-4-(9-phenanthryl)-dihy-dropyrimidine 22 was prepared and isolated in enantiomerically pure form, then attached to a macroporous polymer support. To attach the isolated selector to the amino functionalized macroporous polymethacrylate support, a suitable reactive handle had to be introduced into the dihydropyrimidine. We chose to functionalize the methyl group at the C6 carbon atom by a simple bromination to afford (-)-22. Coupling of this compound to the amino functionalized support then gave the desired chiral stationary phase CSP 12 (Scheme 3-6) containing 0.20 mmol g of the selector. 

Two methods are used in practice to obtain enantiomerically pure amino acids. One way is to resolve the racemic mixture into its pure enantiomers (Section 9.8). A more direct approach, however, is to use an enantioselective synthesis to prepare only the desired 5 enantiomer directly. As discussed in the Chapter 19 Focus Oil, the idea behind enantioselective synthesis is to find a chiral reaction catalyst that will temporarily hold a substrate molecule in an unsymmetrical environment. While in that chiral environment, the substrate may be more... 

The synthetic problem is now reduced to the development of a feasible, large-scale preparation of enantiomerically pure (/ )-citro-nellal (36), which has a single stereogenic center. One way in which the aldehyde function in 36 could be introduced is through the hydrolysis of a terminal enamine. (/ )-CitronelIal (36) can thus be traced to citronellal ( )-diethylenamine (44), the projected product of an enantioselective isomerization of prochiral diethylgera-... 

Recently, Lee and co-workers reported an efficient method for the preparation of enantiomerically pure oxazolidin-2-ones from aziridine-2-carboxylates 186 (Scheme 3.68) [128]. This one-pot aziridine ring-opening and subsequent intramolecular cyclization process was highly regio- and stereoselective, affording 187 in high yield. 

Systematic studies of additions to a-amino ketones are unavailable. One reason may be that the synthesis of enantiomerically pure a-amino ketones has been problematic, however, convenient preparations of various a-amino ketones are now known74-79. 

The enantiomerically pure (/ )- and (iS )-ketones are prepared from the corresponding enantiomer of mandelic acid by catalytic hydrogenation, treatment of the resulting hexahydroman-delic acid with ethyllithium, and subsequent introduction of the silyl protecting group33. 

The reported preparations of enantiomerically pure chiral iron-acyl complexes have relied upon resolutions of diastereomers. One route1415 (see also Houben-Weyl, Vol. 13/9 a, p 421) employs a resolution of the diastereomeric acylmenlhyloxy complexes (Fe/ )-3 and (FeS )-3 prepared via nucleophilic attack of the chiral menlhyloxide ion of 2 at a carbon monoxide of the iron cation of 1. Subsequent nucleophilic displacement of menthyloxide occurs with inversion at iron to generate the enantiomerically pure iron-acyl complexes (i>)-4 and (f )-4. 

Addition of methyllithium to the enantiomerically pure arene dicarbonylchromium chelate 2, prepared by irradiation of imine l52 [derived from ( 1 )-(S)-tricarbonyl(2-methylbenzalde-hyde)chromium53] and subsequent removal of the chromium moiety provides amine 3 in 72% yield and 94% ee54. Interestingly, addition of methyllithium to imine 1 affords only racemic 3. 

Enantiomerically pure of-dibenzylamino-/V-tosylimines 2 arc accessible from amino acids. Since they are not suitable for storage it is advantageous to prepare them in situ from the corresponding aldehydes 1 and A-sulfmyl-4-toluenesulfonamide immediately before use. Addition of Grignard reagents affords the protected 1,2-diamines 3 in good yields (57-95%) and diastereoselectivities (d.r. 85 15 >95 5)8. Deprotection is achieved without racenuzation by reductive methods, see 4-6. 

The enantiomerically pure vinylic organolithium reagent 8 is prepared from (A )-ethyl lactate in four steps. Subsequent addition of A-mesitylsulfonylimines 7 (they provide better diastereo-selectivilies than the corresponding jV-Losylimines) at — 110°C in tetrahydrofuran affords the adducts 9a and 9b in moderate yields (20-63%) but high diaslereoselectivities (d.r. 96 4 — 98 2)l0. 

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