Stereogenic centers, and

Fischer projection formulas can be used to represent molecules with several stereogenic centers and are commonly used for caibohydrates. For other types of structures, a more common practice is to draw the molecule in an extended conformation witii the main chain horizontal. In this arrangement, each tetrahedral caibon has two additional substituents, one facing out and one in. The orientation is specified widi solid wedged bonds for substituents facing out and with dashed bonds for substituents that point in. 

The final step is the nucleophilic displacement of the oxyphosphonium group by the carboxylate anion via a SN2-mechanism, yielding ester 3 with inverted configuration at the stereogenic center, and triphenylphosphine oxide. A hydrolysis of the ester 3 will leave the new configuration unchanged, and yield the inverted alcohol 4 ... 

We have reached a critical stage in the synthesis. Intermediates 2 and 3 represent the left- and right-wing sectors of monensin, respectively. Taken together, these two key building blocks account for 15 of monensin s 17 stereogenic centers, and both are suitably... 

Scheme 6a presents the synthesis of fragment 15. Intermediate 15 harbors two vicinal stereogenic centers, and is assembled in a very straightforward manner through the use of asymmetric aldol methodology. Treatment of the boron enolate derived from 21 with 3-[(p-methoxybenzyl)oxy]propanal (22) affords crystalline syn aldol adduct 34 in 87 % yield as a single diastereomer. Transamination to the A-methoxy-A-methylamide,20 followed by silylation of the secondary hydroxyl group at C-19 with triethylsilyl chloride, provides intermediate 15 in 91 % yield. 

The C29-C34 fragment, trans vinyl iodide 159, is distinguished by two contiguous stereogenic centers, and it was surmised that both could be introduced in a single step through the application of Brown s effective asymmetric crotylboration methodology (see Scheme 48).79 Depro-... 

Nonperpendicular attack of the nucleophile explains Felkin s hypothesis for the predominance of interactions involving R1 and R2 over interactions involving the carbonyl oxygen. Additionally, as R1 increases in bulk, the nucleophile is pushed towards the stereogenic center and can better feel" the difference between the substituents, resulting in an increase in stereoselectivity. 

In accord with the Felkin-Anh model, a-chiral ketones react more diastereoselectively than the corresponding aldehydes. Increasing steric demand of the acyl substituent increases the Cram selectivity. Due to the size of the acyl substituent, the incoming nucleophile is pushed towards the stereogenic center and therefore the diastereoface selection becomes more effective (see also Section 1.3.1.1.). Thus, addition of methyllithium to 4-methyl-4-phenyl-3-hexanonc (15) proceeds with higher diastercoselectivity than the addition of ethyllithium to 3-methyl-3-phenyl-2-pen-tanone (14)32. 

In considering the retrosynthetic analysis of juvabione, two factors draw special attention to the bond between C(4) and C(7). First, this bond establishes the stereochemistry of the molecule. The C(4) and C(7) carbons are stereogenic centers and their relative configuration determines the diastereomeric structure. In a stereocontrolled synthesis, it is necessary to establish the desired stereochemistry at C(4) and C(7). The C(4)-C(7) bond also connects the side chain to the cyclohexene ring. As a cyclohexane derivative is a logical candidate for one key intermediate, the C(4)-C(7) bond is a potential bond disconnection. 

For a facial selective assembly ofthe stereogenic centers and the introduction of the amino functionality, chiral nitrogen-containing reagents, such as benzyl(2-pheny-lethyl)amine (2-19) and trimethylsilyl RAMP derivative 2-24 were applied. Treatment of diacrylates 2-18, 2-21, and 2-23 with 2-19 and 2-24, respectively, gave the protected amino acids 2-20, 2-22, and 2-25 in good yields as single isomers. 

Lactide (LA), the cyclic diester of lactic acid, has two stereogenic centers and hence exists as three stereoisomers L-lactide (S,S), D-lactide (R,R), and meso-lactide (R,S). In addition, rac-lactide, a commercially available racemic mixture of the (R,R) and (S,S) forms, is also frequently studied. PLA may exhibit several stereoregular architectures (in addition to the non-stereoregular atactic form), namely isotactic, syndiotactic, and heterotactic (Scheme 15). The purely isotactic form may be readily prepared from the ROP of L-LA (or D-LA), assuming that epimerization does not occur during ring opening. The physical properties, and hence medical uses, of the different stereoisomers of PLA and their copolymers vary widely and the reader is directed to several recent reviews for more information.736 740-743... 

The preparation of chiral allyltitanium reagents having a stereogenic center and their utilization in asymmetric synthesis have been pursued. As shown in Eq. 9.27, chiral allyl-... 

An interesting pericyclic-anionic-pericyclic domino reaction showing a high stereoselectivity is the cycloaddition-aldol-retro-ene process depicted in scheme 20.1581 The procedure presumably starts with a [4+2]-cycloaddition of diene 98 and S02 in presence of a Lewis acid. After opening of the formed adduct reaction with (Z)-silyl vinyl ether 99 leads to a mixture of alk-2-enesulfinic acids 101. It follows a retro-ene reaction which affords a 7 3 mixture of the products 102 and 103. The reaction described by Vogel et al is a nice example for the efficient generation of polypropionate chains with the stereoselective formation of three stereogenic centers and one (0-double bond in a three-component domino reaction in its strict definition. 

Bicyclic silyloxypyrrole, via the selective formation of a quaternary stereogenic center and a ring-closing metathesis as the main steps, was converted into new polyhydroxyindolizidines <2006TA53>. 

Due to the distance between the stereogenic center and the place of the nucleophilic attack, the enantioselective 1,5-substitution of chiral enyne acetates constitutes one of the rare cases of remote stereocontrol in organocopper chemistry. Moreover, the method is not limited to substrate 51, but can also be applied to the synthesis of enantiomerically enriched or pure vinylallenes 53-57 with variable substituent patterns (Scheme 2.20) [28]. 

A simple epoxy alkanol to begin with is 1,2-epoxyhexan-3-ol (10.47), which has been postulated as a metabolite of the air pollutant hex-l-ene (10.46). This compound was found to be a good substrate for rat liver microsomal EH, yielding hexane-1,2,3-triol (10.48) [127], 1,2-Epoxyhexan-3-ol contains two stereogenic centers and exists as four stereoisomers that were hydrated at different rates, in the order (2S,3R)-erythro > (2S,3S)-threo > ( 2R,3S)-erythro > (2R,3R)-threo. In other words, the metabolic hydrolysis of this substrate is not influenced by the configuration at C(3), but clearly by that at C(2), with the (25)-epimers being better substrates than the (2/7)-cpi-... 

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