Stereochemistry diastereoselective anti-addition

More recently, Apeloig and Nakash have studied diastereoselectivity in the reaction of (E)-5 with p-methoxyphenol53. In both benzene and THF, the stereochemistry of the products was independent of the phenol concentration. The syn/anti ratios of the addition products were 90 10 in benzene and 20 80 in THF. They have suggested that intramolecular proton transfer after rotation of the Si—Si bond of the phenol-coordinated intermediate is responsible for the formation of the anti-addition rather than intermolecular proton transfer. This must be a special case due to much slower (by a factor of 109-1012) rates of addition of phenol to (E)-5. Since phenolic oxygen is definitely less basic than alkyl alcoholic oxygen, coordination of oxygen in the zwitterionic intermediate in the reaction of (E)-5 with phenol must be loose and hence the intermediates should have much chance of rotation around the Si—Si bond. 

Lithium divinyl cuprates.5 The addition of vinylic cuprates to chiral y-alkoxy-a,P-unsaturated ketones and esters proceeds with high diastereoselectivity the major product is that in which the vinyl group is anti to the ally lie alkoxyl group. The geometry of the unsaturated system does not affect the stereochemistry of the addition. 

The anti addition of amines to the double bond of cationic (alkene)(cyclopentadienyl)di-carbonyliron complexes and to the analogous molybdenum and tungsten complexes has been reported31 33. The adducts underwent carbonyl insertion-cyclization to give chelate complexes, which were then oxidized to /8-lactams. For example, from the Fp complexes of ( )- and (Z)-2-butene the corresponding /8-lactams were obtained diastereoselectively in 10-15% yield by the direct oxidation of the benzylamine adducts with chlorine at low temperature33. The stereochemistry was determined by H-NMR spectroscopy. 

The validity of the model was demonstrated by reacting 35 under the same reaction conditions as expected, only one diastereoisomer 41 was formed, the structure of which was confirmed by X-ray analysis. When the vinylation was carried out on the isothiazolinone 42 followed by oxidation to 40, the dimeric compound 43 was obtained, showing that the endo-anti transition state is the preferred one. To confirm the result, the vinyl derivative 42 was oxidized and the intermediate 40 trapped in situ with N-phenylmaleimide. The reaction appeared to be completely diastereoselective and a single diastereomer endo-anti 44 was obtained. In addition, calculations modelling the reactivity of the dienes indicated that the stereochemistry of the cycloaddition may be altered by variation of the reaction solvent. 

Another class of configurationally stable a-mctallo amines is derived from the N-tert-butoxy-carbonyl-protected piperidines 32 and 3516, l7. Addition of the lithiated piperidines to aldehydes leads to mixtures of the anti- and. yin-diastereoiners. Although the diastereoselectivity is low, the diastereomers can be readily separated by chromatography since the. vyn-isomer is often in a cyclized form 34. The stereochemistry of the products obtained from piperidines 32 are consistent with an equatorial a-lithiation followed by addition to the aldehyde with retention of configuration. However, with piperidine 35 selective axial lithiation is observed. 

Consecutive Michael additions and alkylations can also be used for the diastereoselective synthesis of 5- and 6-membered ring systems. For instance when 6-iodo-2-hexenoates or 7-iodo-2-heptenoates are employed the enolate of the Michael adduct is stereoselectively quenched in situ to provide the cyclic compound with trans stereochemistry (>94 6 diastereomeric ratio). As the enolate geometry of the Michael donor can be controlled, high stereoselectivity can also be reached towards either the syn or anti configuration at the exocyclic... 

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. 

If the substituents are nonpolar, such as an alkyl or aryl group, the control is exerted mainly by steric effects. In particular, for a-substituted aldehydes, the Felkin TS model can be taken as the starting point for analysis, in combination with the cyclic TS. (See Section 2.4.1.3, Part A to review the Felkin model.) The analysis and prediction of the direction of the preferred reaction depends on the same principles as for simple diastereoselectivity and are done by consideration of the attractive and repulsive interactions in the presumed TS. In the Felkin model for nucleophilic addition to carbonyl centers the larger a-substituent is aligned anti to the approaching enolate and yields the 3,4-syn product. If reaction occurs by an alternative approach, the stereochemistry is reversed, and this is called an anti-Felkin approach. 

Additions of hydride donors to oc-chiral carbonyl compounds that bear only hydrocarbon groups or hydrogen at C-oc typically take place with the diastereoselectivities of Figure 10.14. One of the resulting diastereomers and the relative configuration of its stereocenters are referred to as the Cram product. The other diastereomer that results and its stereochemistry are referred to with the term anti-Cram product. 

The results of the reaction of lithiated 48 with various aldehydes are reported in Table 5. In each case studied all four possible racemic diastereomeric products were formed. In the case of benzaldehyde a much higher diastereoselectivity could be realized if the aldehyde was precomplexed with BF3 etherate prior to addition to lithiated 48. The major (50s) and the second most prominent diastereomeric products (51a) had the syn (7, 2 = 1.8-2 Hz) and anti (7,2 = 9.3-10 Hz) relative stereochemistry, respectively, 2 while the former diastereoisomer showed a SMe resonance at lower field relative to the latter. 

The addition of alkoxycarbonyl nitrenes, generated photochemically from azides, to substituted dihydropyrans and tri-O-acetyl-D-glycal57"59 in alcoholic solution gave the products of alcoholysis 30 and 31-33 of the intermediate aziridines by a one-pot procedure59. The attack of the nitrene takes place mainly on the less hindered face of the double bond, but complete control of the diastereoselectivity was not accomplished even the ring opening of the aziridine can follow both anti and syn stereochemistry. 

More recently, Alexakis [32] reported the diastereoselective syn- or anti-opening of propargyl epoxides, with good to excellent 8 2 selectivity. Addition of two equivalents of phosphine as a ligand can influence the stereochemistry of the elimination step to afford either the syn- or anti-product, as shown in Eq. (73) and Table 19. 

The stereochemistry of the elimination of the p-hydroxysilane at silicon has been investigated. In studies by Larson and coworkers, the 3-hydroxyalkyl(l-iuq)hthyl)phenylmethylsilanes (307) and (309) were isolated and subjected to elimination conditions to ascertain the stereochemistry of the elimination on the silyl groip (Scheme 44). The acid-catalyzed eliminations proceed with inversion of stereochemistry at silicon, while the base-catalyzed elimination occurred with retention. These results are in agreement with the mechanism proposed of anti elimination under acidic conditions and syn elimination under basic. While the optically pure silicon was useful for determining the course of the elimination, it could not be utilized in asymmetric synthesis. Addition of the anion to various carbonyls afforded virtually no diastereoselectivity, and it was not possible to separate the diastereomers formed either by crystallization or by chromatography. 

Reaction of the /y-benzyloxy-o-methyl chiral aldehyde 97a with (/ )-crolylsi-lanes 217 (R = H, Et) under catalysis by TiC affords the ann,antt-dipropionate adduct 362 (Eq. (11.29)). The diastereoselectivity in this reaction is best explained by anti S e addition of the chiral crotylsilane to the least hindered face of the fi-alkoxy aldehyde chelate, as shown in the synclinal transition state 363. Finally, the anri.syn-dipropionate 364 may be obtained as the major adduct when aldehyde 97a is treated under the same conditions with the enantiomeric crotylsilane reagents (5)-217 (Eq. (11.30), R=Me, Et). This adduct should arise from the antiperiplanar transition state 365, where the anti S e facial selectivity of the crotylsilane reagent and the facial bias of the chiral aldehyde are maintained. In these cases, the factors that dictate the utilization of the synclinal vs the antiperiplanar transition states are (1) the requirement that a small substituent (H) occupy the position over the chelate ring, (2) that C-C bond formation occurs anti to the sterically demanding a-methyl group of the aldehyde and (3) the requirement for an anti Se mechanism, which dictates the stereochemistry of C(5) of the adducts 362 and 364. 

Addition of diethyl aluminum chloride at — 78 °C to a,/ -unsaturated oxazolidinone (154) affords an aluminum enolate that, on hydroxylation with (63a), gives the / -ethyl-a-hydroxy amide (155) with high anti selectivity (Equation (38)) <91AG(E)694>. Formation of the enolate of oxazoline thiol ester (156) under chelation (NaHMDS) and stereoelectronic (NaHMDS/HMPA) control gives the syn and anti alcohols (157), respectively, on hydroxylation with (63a) in good to excellent yield and better than 95% diastereoselectivity (Scheme 28) <93JOC6180>. A counterion dependent reversal in stereochemistry has also been reported for the hydroxylation of chiral amide enolates where the auxiliary was 2-pyrrolidinemethanol <85TL3539>. 

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