Facial diastereoselectivity

The 3- and 6-acetoxyvinylcyclohexenes 53 and 54 react with dimethyl-acetylenedicarboxylate to afford bicyclic esters [50]. It is noteworthy that the facial diastereoselectivity depends on the position of the acetoxy group (Scheme 2.21). While the reaction of 53 is completely uwtz-diastereoselect-ive, that of 54 is undiastereoselective, affording a 1 1 mixture of cycloadducts. 

The cycloadditions of the C-2 vinyl glicals with maleic anhydride are an interesting example of facial stereocontrol. The allylic methoxy group in dienes 55a and 55b exerts an nnh -stereodirecting effect as shown by the stereochemistry of the endo-cycloadducts 56 and 57 obtained as the sole products from 55a and 55b, respectively, and by the fact that 55c produces [51] a mixture of the diastereoisomers 56c and 57c (Scheme 2.22). When linear acetylenic dienophiles were used, the degree of facial diastereoselectivity decreased, which indicates its dependence on steric effects. 

Tetraene 141 has been converted into various complex polycondensed adducts by reacting with a variety of dienophiles such as maleic anhydride, N-phenylmaleimide, N-phenyltriazolinedione,p-benzoquinone and tetracyano-ethylene carried out under thermal conditions. All cycloadditions occurred facial-diastereoselectively from an outside attack and provided monocycloadducts which had an exceptionally close relationship between diene and dieno-phile and then underwent intramolecular cycloaddition [125]. The reaction between 141 and p-benzoquinone is illustrated in Scheme 2.53. 

Fallis A. G., Lu Y. F. TT-Facial Diastereoselection in Diels-Alder Cycloadditions and Related Reactions Understanding Planar Interactions and Establishing Synthetic Potential Adv. Cydoaddit. 1993 3 1-66... 

Summary of the Relationship between Diastereoselectivity and the Transition Structure. In this section we considered simple diastereoselection in aldol reactions of ketone enolates. Numerous observations on the reactions of enolates of ketones and related compounds are consistent with the general concept of a chairlike TS.35 These reactions show a consistent E - anti Z - syn relationship. Noncyclic TSs have more variable diastereoselectivity. The prediction or interpretation of the specific ratio of syn and anti product from any given reaction requires assessment of several variables (1) What is the stereochemical composition of the enolate (2) Does the Lewis acid promote tight coordination with both the carbonyl and enolate oxygen atoms and thereby favor a cyclic TS (3) Does the TS have a chairlike conformation (4) Are there additional Lewis base coordination sites in either reactant that can lead to reaction through a chelated TS Another factor comes into play if either the aldehyde or the enolate, or both, are chiral. In that case, facial selectivity becomes an issue and this is considered in Section 2.1.5. 

In the discussion of the stereochemistry of aldol and Mukaiyama reactions, the most important factors in determining the syn or anti diastereoselectivity were identified as the nature of the TS (cyclic, open, or chelated) and the configuration (E or Z) of the enolate. If either the aldehyde or enolate is chiral, an additional factor enters the picture. The aldehyde or enolate then has two nonidentical faces and the stereochemical outcome will depend on facial selectivity. In principle, this applies to any stereocenter in the molecule, but the strongest and most studied effects are those of a- and (3-substituents. If the aldehyde is chiral, particularly when the stereogenic center is adjacent to the carbonyl group, the competition between the two diastereotopic faces of the carbonyl group determines the stereochemical outcome of the reaction. 

The stereogenic centers may be integral parts of the reactants, but chiral auxiliaries can also be used to impart facial diastereoselectivity and permit eventual isolation of enantiomerically enriched product. Alternatively, use of chiral Lewis acids as catalysts can also achieve facial selectivity. Although the general principles of control of the stereochemistry of aldol addition reactions have been well developed for simple molecules, the application of the principles to more complex molecules and the... 

Stereochemical Control by the Aldehyde. A chiral center in an aldehyde can influence the direction of approach by an enolate or other nucleophile. This facial selectivity is in addition to the simple syn, anti diastereoselectivity so that if either the aldehyde or enolate contains a stereocenter, four stereoisomers are possible. There are four possible chairlike TSs, of which two lead to syn product from the Z-enolate and two to anti product from the A-enolate. The two members of each pair differ in the facial approach to the aldehyde and give products of opposite configuration at both of the newly formed stereocenters. If the substituted aldehyde is racemic, the enantiomeric products will be formed, making a total of eight stereoisomers possible. 

Scheme 2.3 shows reactions of several substituted aldehydes of varying complexity that illustrate aldehyde facial diastereoselectivity in the aldol and Mukaiyama reactions. The stereoselectivity of the new bond formation depends on the effect that reactant substituents have on the detailed structure of the TS. The 3,4-syn stereoselectivity of Entry 1 derives from a Felkin-type acyclic TS. 

Entry 2 involves the use of a sterically biased enol boronate with an a-substituted aldehyde. The reaction, which gives 40 1 facial selectivity, was used in the synthesis of 6-deoxyerythronolide B and was one of the early demonstrations of the power of double diastereoselection in synthesis. In Entry 3, the syn selectivity is the result of a chelated TS, in which the (3-p-methoxybenzyl substituent interacts with the tin ion.120... 

With titanium enolates it was found that use of excess (3 equiv.) of the titanium reagent reversed facial selectivity of oxazolidinone enolates.140 This was attributed to generation of a chelated TS in the presence of the excess Lewis acid. The chelation rotates the oxazolidinone ring and reverses the facial preference, while retaining the Z-configuration syn diastereoselectivity. 

Prediction and analysis of diastereoselectivity are based on steric, stereoelectronic, and complexing interactions in the TS.82 In the case of the lactic acid auxiliary, a chelated structure promotes facial selectivity. In the TiCl4 complex of 0-acryloyl ethyl lactate,... 

Mandelate and lactate esters have been found to generate diastereoselectivity in reactions of hydroxy-substituted quinodimethanes generated by thermolysis of benzo-cyclobutenols.88 The reactions are thought to proceed by an exo TS with a crucial hydrogen bond between the hydroxy group and a dienophile carbonyl. The phenyl (or methyl in the case of lactate) group promotes facial selectivity. 

Note Added in Proof. The stereochemistry of the Diels-Alder addition reactions shown in Scheme 1 to give products 20-22 has been examined by 400 MHz lH-NMR. These data indicate that the cycloadditions occur with a high degree of stereoselectivity (having diastereoselectivities of greater than 94 6). The chiral Fe environment of the dienophile 17 strongly influences the direction of the facial attack of the diene reactants. 

High facial diastereoselectivity has been reported in the [2+2] photocycloaddition of aromatic aldehydes with a chiral enamide to give the ds-2,3-disubstituted oxetanes 11 and 12 with only minor amounts of the trans-oxetanes <99TL9003>. The same group of workers have investigated the photocycloaddition of m-substituted benzaldehydes to 3,4-dihydro-l.H-pyridin-2-ones to give mainly 13 <99JA10650>. 

High diastereomeric ratios were observed in the 1,3-DC of various nitrile oxides to the chiral acryloylhydrazide 38. For example benzonitrile oxide afforded the isoxazoline 40 in 98% de <00TL1453>. The levels of facial selectivity obtained in the same 1,3-DC with the chiral 3-acryloyl-2-oxazolidinone 39 was very low (dr 43 57), but in the presence of MgBr2 (1 equiv) the reaction proceeded with high diastereoselectivity to give preferentially the isoxazolidine 41 in 92% de <00TL3131>. 

When comparing these results with those previously obtained using carbohydrate-based vinyl ethers as chiral dienophiles, this improved facial diastereoselectivity to heterodienes under similar conditions is noteworthy.81 The efficient chiral transfer in the second example might mostly be attributed to the specific architecture of the l,2 5,6-di-0-isopropylidene-a-D-glucofuranose moiety.Those findings open the way to develop well-defined spiro-carbohydrate templates towards improved auxiliaries for chirality transfer in a wide range of syntheses. 

Another example, in which the piperidine cycle is generated de novo, exploits a hetero Diels-Alder cycloaddition of 1 -/r-tolylsulfinyl-1,3-penta-diene 91 with benzylnitrosoformate, that generates an oxazine 92 with complete regioselectivity and 7i-facial diastereoselectivity.69 Osmilation of the double bond inserts stereoselectively two hydroxyl groups on the oxazine skeleton, protection and catalytic hydrogenation finally afforded the enantiomerically pure imino sugars 94 (Fig. 38). 

An enantioselective intramolecular Pauson-Khand reaction based on chiral auxiliary-directed 7t-face discrimination in acetylenic 0-alkyl enol ether-dicobalt hexacarbonyl complexes, which proceeds with good yields and high facial diastereoselectivity, has recently been developed by M.A. Pericas, A. Moyano, A.E. Greene and their associates. The method has been applied to an enantioselective formal synthesis of hirsutene. Moreover, the process is stereodivergent and the chiral auxiliary -rran5-2-phenylcyclohexanol- is recovered in a yield as high as 92% [18]. 

The central point of Evans s methodology is the induction of a 7t-enantiotopic facial differentiation through a conformationally rigid highly ordered transition state. Since the dialkylboron enolates of AT-acyl-2-oxazolidinones exhibit excellent syn-diastereoselectivity syn.anti >97 3) when reacted with a variety of aldehydes, Evans [14] studied the aldol condensation with the chiral equivalents 32 and 38. which are synthesised from fS)-valine (35) and the hydrochloride of (15, 2R)-norephedrine (36) (Scheme 9.11), respectively, and presently are commercially available. 

The reaction of 5(4H)-oxazolones (32) and miinchnones with triphenylvinylphos-phonium bromide (33) provides a mild synthesis of substituted pyrroles (34) (Scheme 11). The cycloaddition-elimination reactions of 5-imino-l,2,4-thiadiazolidin-3-ones with enamines and ester enolates produce 2-iminothiazolidines. " Chiral isomtinchnone dipoles show jr-facial diastereoselectivity with IV-phenyl- or A -methyl-maleimide in refluxing benzene. ... 

Racemic diquinane enone rac-6 was prepared by Piers and Orellana starting from cyclopentenone (Scheme 6) [11]. After the preparation of the heterocuprate from stannane 20, conjugate addition to cyclopentenone in the presence of BF3 Et20 provided carbonyl compound 21. It was expected that conversion of 21 by intramolecular alkylation and subsequent hydrogenation should provide the desired endo-substituted diquinane rac-13. While other hydrogenation methods proved to be rather unselective, reduction in the presence of Wilkinson s catalyst finally resulted in the formation of rac-13 with good facial diastereoselectivity [11]. 

---