Stereochemistry diastereomers formations

It is known that electrochemical reduction of oximes in protic media occurs in two steps the N—O bond is first reduced to form an imine and the latter is then reduced to afford a primary amine1,29. Tallec has shown that the amine from oxime 33 can be trapped intramolecularly (equation 16)35. Interestingly, the SS diastereomer predominates the chiral pyrrolidine ring derivative serves to control the stereochemistry of formation of the new benzylic chiral center. Electrochemical reductive cross-coupling of O-methyl oximes with carbonyl compounds in isopropanol at a tin cathode affords adducts (equation 17) which can be reduced further to 2-amino alcohols36. In this fashion, menthone could... 

I-Oialkoxy carbonyl compounds are a special class of chiral alkoxy carbonyl compounds because they combine the structural features, and, therefore, also the stereochemical behavior, of 7-alkoxy and /i-alkoxy carbonyl compounds. Prediction of the stereochemical outcome of nucleophilic additions to these substrates is very difficult and often impossible. As exemplified with isopropylidene glyceraldehyde (Table 15), one of the most widely investigated a,/J-di-alkoxy carbonyl compoundsI0S, the predominant formation of the syn-diastereomer 2 may be attributed to the formation of the a-chelate 1 A. The opposite stereochemistry can be rationalized by assuming the Felkin-Anh-type transition state IB. Formation of the /(-chelate 1C, which stabilizes the Felkin-Anh transition state, also leads to the predominant formation of the atm -diastereomeric reaction product. 

Thus chelation control " may lead to either product, depending on the relative stabilities of the respective ot- and /(-chelates. In cases with predominant formation of the anri-diastereomer, it is often difficult to establish whether the formation of a /(-chelate or an open-chain Felkin - Anh transition state is responsible for the observed stereochemistry the decision usually rests on plausibility considerations. Thus, with regard to the results obtained for a-alkoxy carbonyl... 

Investigations on the stereochemistry of chiral semiochemicals may be carried out by (gas) chromatographic separation of stereoisomers using chiral stationary phases, e.g. modified cyclodextrins [32]. Alter natively, formation of diastereomers (e.g. Mosher s ester or derivatives involving lactic acid etc.) may be followed by separation on conventional achiral stationary phases. Assignment of the absolute configuration of the natural product will again need comparison with an authentic (synthetic) reference sample. 

In all of the cases described above, characterization of the product macrocycles was complicated by the presence of up to two diastereomers per U4CR. Induction of stereochemistry is typically low in Ugi reactions, and the formation of four new stereocenters in 114, for example, probably... 

Although one diastereomer 10 was largely favored, the product was obtained as a mixture of diastereomers, and the previously unreported minor diastereomer 11 was also characterized. The stereochemistry of the products was established by nuclear Overhauser effect (NOE) studies. A plausible mechanism assumes the intermediacy of an acetal, and its reaction with 2-methoxypropene generated from 2,2-dimethoxypropane [20]. In order to test this mechanism, the dimethyl acetal of salicylaldehyde was synthesized and reacted independently with both 2,2-dimethoxypropane and 2-methoxypropene. Indeed, both reactions gave the same products as those from the reaction of salicylaldehyde with 2,2-dimethoxypropane (Scheme 4). The condensation of salicylaldehyde and 2,2-dimethoxypropane was also carried out in CD3CN and reaction progress was followed by H NMR spectroscopy. This experiment also confirmed the formation of the acetal from salicylaldehyde (8 5.52, singlet, C//(OMe)2). 

Mori has reported the nickel-catalyzed cyclization/hydrosilylation of dienals to form protected alkenylcycloalk-anols." For example, reaction of 4-benzyloxymethyl-5,7-octadienal 48a and triethylsilane catalyzed by a 1 2 mixture of Ni(GOD)2 and PPhs in toluene at room temperature gave the silyloxycyclopentane 49a in 70% yield with exclusive formation of the m,//7 //i -diastereomer (Scheme 14). In a similar manner, the 6,8-nonadienal 48b underwent nickel-catalyzed reaction to form silyloxycyclohexane 49b in 71% yield with exclusive formation of the // /i ,// /i -diastereomer, and the 7,9-decadienal 48c underwent reaction to form silyloxycycloheptane 49c in 66% yield with undetermined stereochemistry (Scheme 14). On the basis of related stoichiometric experiments, Mori proposed a mechanism for the nickel-catalyzed cyclization/hydrosilylation of dienals involving initial insertion of the diene moiety into the Ni-H bond of a silylnickel hydride complex to form the (7r-allyl)nickel silyl complex li (Scheme 15). Intramolecular carbometallation followed by O-Si reductive elimination and H-Si oxidative addition would release the silyloxycycloalkane with regeneration of the active silylnickel hydride catalyst. 

The formation of oxazolidines 54 or oxazolidinones 55 is currently utilized to assign the absolute stereochemistry of diastereomers of 1,2-amino alcohols, based on H NMR analysis of the H4 and H5 protons of these heterocycles. In the case of y-amino-p-hydroxy acids, the internally cyclized pyrrolidinone 56 is also suitable for determination of the relative configurations of the y-amino and p-hydroxy groups (Scheme 23). 

The reaction with N-Boc-pyrrolidine may be taken a step further by inducing a double C-H insertion sequence [27]. This results in the formation of the elaborate C2-symmetric amine 35 as a single diastereomer with control of stereochemistry at four stereogenic centers. The enantiomeric purity of 35 is higher than that obtained for the single C-H insertion products, presumably because kinetic resolution is occurring in the second C-H insertion step. 

The introduction of a bulky, optically active amino function at C-2 of 4-phenyl-l-thiabutadiene and activation by the addition of AcCl prior to cycloaddition with Wphenylmaleimide, known to exhibit a high endo preference, results in the formation of two diastereomers. However, the exo product is the major component and indeed this diastereo-mer is the sole adduct when cyclopentene is used as the dienophile. Calculations point to a preference for exo addition from the same face of the molecule as the naphthyl moiety and this is supported by the observed R stereochemistry at the three chiral centers in the cyclopenta[A]dihydrothiopyran 434 (Scheme 140) <1996TL123>. 

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