Diastereoselectivity relative

S-aryl), concomitant sulfoxidation can be observed and the diastereoselectivity relative to the cis-diol depends on the nature of the sulfur substituents [239]. 

An interesting example exists of variation of diastereoselectivity, due both to the nature and sense of chirality of the electrophile, and to the configuration of the 2-pyrrolidinemethanol auxiliary6. Thus, the use of epoxide 16 as electrophile leads to an unexpected reversal of the diastereoselectivity relative to that observed when the corresponding O-protected iodohydrin 10 is employed. Both of the electrophiles are chiral and therefore reaction of each with the enantiomers of 1-(l-oxopropyl)-2-pyrrolidinemethanol leads to different diastereoselectivities due to the fact that there is a matched and a mismatched pair of reactions. 

The molybdenum(VI) complex with BIPHEN (Schrock-Hoveyda catalyst) has been widely used as an enantioselective olefin metathesis catalyst for a variety of substrates (145). Recently, the synthesis of a tetrahydrocannabiol derivative in molybdenum-catalyzed asymmetric allylic alkylation by using Trost-ligands is carried out. Enhanced regio-, enantio-, and diastereoselectivities relative to the palladium ones have been observed (146). 

Asymmetric induction can be also accomplished through the use of a chirally modified nitro olefin. Sugar-based nitroalkenes participate in thermal [4 + 2] cycloaddition to form enantiomerically pure nitronates [55,97]. Alternatively, diastereoselective cycloadditions are possible with chiral nitroalkenes as illustrated on Scheme 16.15 [47]. The tandem double intramolecular cycloaddition of enantiopure nitro-alkene 62 containing a single stereogenic center provides nitroso acetal 63 with high diastereoselectivity (relative to the existing center) in moderate yield. The product is isolated as a mixture of isomers that is formed due to epimerization of the intermediate nitronate (not shown) and used toward total synthesis of daphnilactone B. 

Several factors influence the diastereoselectivity of the Pictet-Spengler condensation to form 1,3-disubstituted and 1,2,3-trisubstituted tetrahydro-P-carbolines (39 and 40, respectively). The presence or absence of an alkyl substituent on the nitrogen of tryptophan has a large influence on the relative stereochemistry of the tetrahydro-P-carboline products formed from a condensation reaction with an aldehyde under various reaction conditions. 

The enol ether double bond contained within the ds-fused dioxa-bicyclo[3.2.0]heptene photoadducts can also be oxidized, in a completely diastereoselective fashion, with mCPBA. Treatment of intermediate XXII, derived in one step from a Patemo-Buchi reaction between 3,4-dimethylfuran and benzaldehyde, with mCPBA results in the formation of intermediate XXIII. Once again, consecutive photocycloaddition and oxidation reactions furnish a highly oxygenated system that possesses five contiguous stereocenters, one of which is quaternary. Intermediate XXIII is particularly interesting because its constitution and its relative stereochemical relationships bear close homology to a portion of a natural product known as asteltoxin. 

Similar to cyclohexanones, substituted cyclopentanones also adopt a conformation with the substituents in a sterically favorable position. In the case of 2-substituted cyclopentanones 1 the substituent occupies a pseudoequatorial position and the diastereoselectivity of nucleophilic addition reactions to 1 is determined by the relative importance of the interactions leading to predominant fra s(equatorial) or cw(axial) attack of the nucleophile. When the nucleophile approaches from the cis side, steric interaction with the substituent at C-2 is encountered. On the other hand, according to Felkin, significant torsional strain between the pseudoaxial C-2—H bond and the incipient bond occurs if the nucleophile approaches the carbonyl group from the trans side. 

On the basis of this analysis, it may be anticipated that the extent of aldehyde diastereofa-cial selectivity will depend on the difference in size of the R3 aldehyde substituent relative to that of the methyl group. The examples summarized in Table 2 are generally supportive of this thesis, particularly the reactions of (F)-2-butenylboronntc. The data cited for reactions of 3-methoxymethoxy-2-methylbutanal with (Z)-2-butenylboronate and 2-propenylboronate, however, also show that diastereoselectivity depends on the stereochemistry at C-3 of the chiral aldehydes. These data imply that simple diastereoselectivity depends not simply on reduced mass considerations, but rather on the stereochemistry and conformation of the R3 substituent in the family of potentially competing transition states21,60. The dependence of aldehyde diastcrcofacial selectivity on the stereochemistry of remote positions of chiral aldehydes has also been documented for reactions involving the ( )-2-butenylchromium reagent62. 

Interestingly, while diastereoselectivity is dependent on the relative size of the two non-hydro-gen substituents a to the aldehyde, selectivity does not appear to be sensitive to increases in the steric requirements of the substituent on the allylboronate21. 

On the other hand, high levels of diastereoselectivity are relatively easy to achieve in matched double asymmetric reactions since the intrinsic diastereofacial preference of the chiral aldehyde reinforces that of the reagent, and in many cases it has been possible to achieve synthetically useful levels of matched diastereoselection by using only moderately enantioselective chiral allylboron reagents. Finally, it is worth reminding the reader that both components of double asymmetric reactions need to be both chiral and nonracemic for maximum diastereoselectivity to be realized. 

Double deprotonation of tetrahydro-2-(2-nilroethoxy)-2//-pyran (8) and reaction with electrophiles provides a variety of substituted and functionalized nitroaldols1 Reaction with aldehydes affords 2-nitro-l,3-alkanediols 9 in 44 90% yield and high diastereoselectivities. From analogy of their II-NMR spectra and comparison with known compounds, the (R, R ) relative configuration is likely15. 

The lithium enolates of cyclopentanone and cyclohexanone undergo addition-elimination to the 2,2-dimethylpropanoic acid ester of ( )-2-nitro-2-hepten-l-ol to give 2-(l-butyl-2-nitro-2-propenyl)cycloalkanones with modest diastereoselection. An analogous reaction of the enolate ion of cyclohexanone with the 2,2-dimethylpropanoic acid ester of (Z)-2-nitro-3-phenyl-2-propenol to give 2-(2-nitro-l-phenyl-2-propenyl)cyclohexanones was also reported. The relative configuration of these products was not however determined6. 

Engberts [3e, f, 9, 29] investigated the influence of metal ions (Co, Ni, Cu +, Zn +) on the reaction rate and diastereoselectivity of Diels-Alder reaction of dienophile 31 (Table 6.5, R = NO2) with cyclopentadiene (32) in water and organic solvents. Relative reaction rates in different media and the catalytic effect of Cu are reported in Table 6.5. 10 m Cu(N03)2 accelerates the reaction in water by 808 times, and when compared with the uncatalyzed reaction in MeCN by a factor of 232 000. 

A recent report [90] investigated the Diels-Alder reaction of cyclopentadiene with various acrylates in SC-CO2 catalyzed by Sc(OTf)j. The results relative to n-butyl acrylate, in SC-CO2 and in conventional solvents, are reported in Scheme 6.34. The catalyzed reaction carried out under supercritical conditions went to completion within 15 h at 50 °C, whereas the uncatalyzed reaction proceeded only to 10 % after 24 h. An increase of endo/exo diastereoselectivity was also observed. 

Sulfonic peracids (66) have also been applied recently to the preparation of acid sensitive oxiranes and for the epoxidation of allylic and homoallylic alcohols, as well as relatively unreactive a, p - unsaturated ketones. These reagents, prepared in situ from the corresponding sulfonyl imidazolides 65, promote the same sense of diastereoselectivity as the conventional peracids, but often to a higher degree. In particular, the epoxidation of certain A -3-ketosteroids (e.g., 67) with sulfonic peracids 66 resulted in the formation of oxirane products (e.g., 68) in remarkably high diastereomeric excess. This increased selectivity is most likely the result of the considerable steric requirements about the sulfur atom, which enhances non-bonded interactions believed to be operative in the diastereoselection mechanism <96TET2957>. 

---