Imines chiral auxiliaries

Extension of this methodology to a triple stereoselective process is reported in reaction D. This completely stereoselective reaction takes advantage of the matching combination between the enolate and the imine chiral auxiliary, which, in its turn is also internally matched with the other imine stereocenter [37]. 

An alternative approach is to have the chiral auxiliary on the enolate. Sweeney has reported the addition of bromoacyl sultam 102 to phosphonyl imines 103, which afforded the cis- or trans-aziridines with high levels of diastereoselectivity depending on the imine substituent (Scheme 1.30) [55]. 

Solladie-Cavallo has recently reported a two-step asymmetric synthesis of dis-ubstituted N-tosylaziridines from (R,R,R,Ss)-(-)-sulfonium salt 2 (derived from Eliel s oxathiane see Section 1.2.1.1) and N-tosyl imines with use of phosphazine base (EtP2) to generate the ylide (Scheme 1.42) [67], Although the diastereoselectiv-ity was highly substrate-dependent, the enantioselectivities obtained were very high (98.7-99.9%). The chiral auxiliary, although used in stoichiometric quantities, could be isolated and reused, but the practicality and scope of this procedure is limited by the use of the strong - as well as expensive and sensitive - phospha-zene base. 

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. 

Mainly sulfoxide groups are introduced as chiral auxiliaries for the modification of a,/J-unsat-urated enones (see Section D.1.5.3.5.). Chiral imine derivatives have also been used (see Section D.1.5.3.1.). Various chiral alcohols, and in particular 8-phenylmenthol, have been successfully used as auxiliaries, mainly in two-fold Michael additions to a,/ -unsaturatcd esters. 

There are many reports on the asymmetric addition of nucleophiles to carbon-nitrogen double bonds [6]. However, the majority of these reports are based on substrate control and rely on chiral auxiliaries in imines. Moreover, almost all of these reports are just for aldo-imine cases [7]. 

Chromium carbene complexes have also been known to react with imine equivalents to afford /3-lactam derivatives234. Furthermore, [3 + 2]-cycloaddition of an alkenylchromium carbene 133 with imines proceeded to afford 3-pyrroline derivatives 134 in the presence of a Lewis acid catalyst (Equation (21)),235 where GaClj or Sn(OTf)2 were efficient promoters. Alkenylcarbenes bearing chiral auxiliaries afforded the desired cycloadduct in optically pure form. 

To complement the above information, a highly enantioselective synthesis of a-amino phosphonate diesters should be mentioned.164 Addition of lithium diethyl phosphite to a variety of chiral imines gives a-amino phosphonate with good to excellent diastereoselectivity (de ranges from 76% to over 98%). The stereoselective addition of the nucleophile can be governed by the preexisting chirality of the chiral auxiliaries (Scheme 2-63). 

In the presence of ZrCU or HC1, cyclization of y - a I k o x y a 11 y I s t a n n a n e 158 bearing (i )-(+)-l-phenylethylamine as a chiral auxiliary occurs to produce trans-fi-aminocyclic ether 159 with high de (91%). As shown in Scheme 3-55, asymmetric addition of an allyl group to the imine carbon can be explained by the modified Cram model 160. The attack of the allylic y-carbon approaches... 

A number of groups have reported the preparation and in situ application of several types of dendrimers with chiral auxiliaries at their periphery in asymmetric catalysis. These chiral dendrimer ligands can be subdivided into three different classes based on the specific position of the chiral auxiliary in the dendrimer structure. The chiral positions may be located at, (1) the periphery, (2) the dendritic core (in the case of a dendron), or (3) throughout the structure. An example of the first class was reported by Meijer et al. [22] who prepared different generations of polypropylene imine) dendrimers which were substituted at the periphery of the dendrimer with chiral aminoalcohols. These surface functionalities act as chiral ligand sites from which chiral alkylzinc aminoalcoholate catalysts can be generated in situ at the dendrimer periphery. These dendrimer systems were tested as catalyst precursors in the catalytic 1,2-addition of diethylzinc to benzaldehyde (see e.g. 13, Scheme 14). 

Enantiomeric excesses of up to 76% have been obtained for alkyllithium-aldehyde condensations using 3-aminopyrrolidine lithium amides as chiral auxiliaries. Addition of organolithiums to imines has been achieved with up to 89% ee, in the presence of C2-symmetric bis(aziridine) ligands. ... 

Numerous studies have been directed toward expanding the chemistry of the donor/ac-ceptor-substituted carbenoids to reactions that form new carbon-heteroatom bonds. It is well established that traditional carbenoids will react with heteroatoms to form ylide intermediates [5]. Similar reactions are possible in the rhodium-catalyzed reactions of methyl phenyldiazoacetate (Scheme 14.20). Several examples of O-H insertions to form ethers 158 [109, 110] and S-H insertions to form thioethers 159 [111] have been reported, while reactions with aldehydes and imines lead to the stereoselective formation of epoxides 160 [112, 113] and aziridines 161 [113]. The use of chiral catalysts and pantolactone as a chiral auxiliary has been explored in many of these reactions but overall the results have been rather moderate. Presumably after ylide formation, the rhodium complex disengages before product formation, causing degradation of any initial asymmetric induction. 

Substituted 1,2,4-oxadiazoles were prepared by addition of nitrile oxides to imines or hydrazones. It has been reported that interaction of hydroximoyl chlorides 262 with chiral hydrazones 263 in the presence of EtsN leads to intermediates 264 with diastereoselectivity up to 97%. A subsequent N-N bond cleavage to remove chiral auxiliary by formic acid leads to 1,2,4-oxadiazolines 265 with ee up to 91% (equation 113). ... 

Enantiomerically pure trans-2-phenylcyclohexanol, first used by Whitesell as a chiral auxiliary has become a popular reagent in a number of asymmetric transformations. Some recent applications include asymmetric azo-ene reactions, [4 + 2]-cycloaddition reactions, ketene-olefin [2 + 2]-reactions, enolate-imine cyclocondensations, Pauson-Khand reactions," palladium annulations and Reformatsky reactions. Despite its potential, use of this chiral auxiliary on a preparative scale is currently limited by its prohibitive cost. 

While nonracemic trifluoroalanines can easily undergo racemization or dehydro-fluorination, many asymmetric syntheses oftrifluoroalanines have been proposed. These syntheses generally involve an asymmetric reduction step of an imine or an enamine. This step can be performed by utilizing either chiral catalysts or chiral auxiliaries. 

Azetidinones on a solid support 49 have been prepared in high yield by Staudinger reaction of a supported imine with an acid chloride in the presence of a base. The liberated p-lactams were of high purity <99TL1249>. Cycloaddition of a ketene intermediate, derived fi"om an azo compound, to an imine having an oxidatively cleavable chiral auxiliary N-substituent was used to obtain p-lactams 50. The trans. cis ratio which varied between 69 31 and 93 7, depended on the nature of the substituents R and R <99S650>. 

Asymmetric alkylation of benzylamine via the imine 6A, with ( + )-D-camphor (5 A) as chiral auxiliary is possible. Deprotonation with butyllithium and subsequent alkylation with haloalkanes, (R X) afforded the alkylated imines 7 A with reasonable yield but variable diastereo-selectivity. The diastereoselectivity depends strongly on the haloalkane with methoxy-substi-tuted halomethylbenzenes moderate to good diastereoselectivity (d.r. 80 20-90 10) is obtained, however, with haloalkanes or 3-halopropenes only low optical purities (< 50%) were observed. 

---