Chiral centers products

This target molecule again contains a chiral center and we inspect Table 18 for help. Table 18. Some enantioselective reactions that produce difunctional products... 

Molecules with chirality centers are very common both as naturally occurring sub stances and as the products of chemical synthesis (Carbons that are part of a double bond or a triple bond can t be chirality centers)... 

Many of the reactions we ve already encountered can yield a chiral product from an achi ral starting material Epoxidation of propene for example creates a chirality center by adding oxygen to the double bond... 

Because there are four chirality centers and no possibility of meso forms there are 2" or 16 stereoisomeric hexoses All 16 are known having been isolated either as natural products or as the products of chemical synthesis... 

Steroids are another class of natural products with multiple chirality centers One such compound is cholic acid which can be obtained from bile Its structural formula IS given m Figure 7 12 Cholic acid has 11 chirality centers and so a total (including cholic acid) of 2" or 2048 stereoisomers have this constitution Of these 2048 stereoiso mers how many are diastereomers of cholic acid s Remember Diastereomers are stereoisomers that are not enantiomers and any object can have only one mirror image Therefore of the 2048 stereoisomers one is cholic acid one is its enantiomer and the other 2046 are diastereomers of cholic acid Only a small fraction of these compounds are known and (+) cholic acid is the only one ever isolated from natural sources... 

When bromine adds to (Z) or (E) 2 butene the product 2 3 dibromobutane con tains two equivalently substituted chirality centers... 

The double bond m 2 methyl(methylene)cyclohexane is prochiral The two faces however are not enantiotopic as they were for the alkenes we discussed m Section 7 9 In those earlier examples when addition to the double bond created a new chirality cen ter attack at one face gave one enantiomer attack at the other gave the other enantiomer In the case of 2 methyl(methylene)cyclohexane which already has one chirality center attack at opposite faces of the double bond gives two products that are diastereomers of each other Prochiral faces of this type are called diastereotopic... 

Section 7 9 A chemical reaction can convert an achiral substance to a chiral one If the product contains a single chirality center it is formed as a racemic mixture Optically active products can be formed from optically inactive... 

Wnte the organic products of each of the following reactions If two stereoisomers are formed show both Label all chirality centers / or 5 as appropriate... 

The reaction is used for the chain extension of aldoses in the synthesis of new or unusual sugars In this case the starting material l arabinose is an abundant natural product and possesses the correct configurations at its three chirality centers for elaboration to the relatively rare l enantiomers of glucose and mannose After cyanohydrin formation the cyano groups are converted to aldehyde functions by hydrogenation m aqueous solution Under these conditions —C=N is reduced to —CH=NH and hydrolyzes rapidly to —CH=0 Use of a poisoned palladium on barium sulfate catalyst prevents further reduction to the alditols... 

Absolute configuration (Section 7 5) The three dimensional arrangement of atoms or groups at a chirality center Acetal (Section 17 8) Product of the reaction of an aldehyde or a ketone with two moles of an alcohol according to the equation... 

Double Fiiedel-Ciafts alkylation of configuiationally pure pyiocene (a substituted lactone) with aiomatics results in the formation of cycloalkylation product with retention of configuration at the chiral center (63). 

Tartaric acid [526-83-0] (2,3-dihydroxybutanedioic acid, 2,3-dihydroxysuccinic acid), C H O, is a dihydroxy dicarboxyhc acid with two chiral centers. It exists as the dextro- and levorotatory acid the meso form (which is inactive owing to internal compensation), and the racemic mixture (which is commonly known as racemic acid). The commercial product in the United States is the natural, dextrorotatory form, (R-R, R )-tartaric acid (L(+)-tartaric acid) [87-69-4]. This enantiomer occurs in grapes as its acid potassium salt (cream of tartar). In the fermentation of wine (qv), this salt forms deposits in the vats free crystallized tartaric acid was first obtained from such fermentation residues by Scheele in 1769. 

Woodward s total synthesis of cephalosporin C begins with L-cysteine (48) which establishes the chiral center at C-7. The cis geometry at C-6,7 is achieved in intermediate (49) which is cyclized to (50) by treatment with triethylaluminum. The dihydrothiazine ring is constructed by Michael addition to the condensation product of trichloroethyl glyoxylate... 

A very important relationship between stereochemistry and reactivity arises in the case of reaction at an 5 carbon adjacent to a chiral center. Using nucleophilic addition to the carbonyl group as an example, it can be seen that two diastereomeric products are possible. The stereoselectivity and predictability of such reactions are important in controlling stereochemistry in synthesis. 

Other mechanisms must also operate, however, to account tor the fact that 5-10% of the product is formed with retained configuration at the chiral center. Isotopic labeling studies have also demonstrated that the 3-bromo-2-butyl radical undergoes reversible loss of bromine atom to give 2-butene at a rate which is competitive with that of the bromination reaction ... 

The reaction of diethyl tartrate with sulfur tetrafluonde at 25 °C results in replacement of one hydroxyl group, whereas at 100 °C, both hydroxyl groups are replaced by fluonne to form a,a -difluorosuccinate [762] The stereochemical outcome of the fluonnation of tartrate esters is retention of configuration at one of the chiral carbon atoms and inversion of configuration at the second chiral center [163,164, 165] Thus, treatment ofdimethyl(+)-L-tartrate with sulfur tetrafluonde gives dimethyl meso-a,a difluorosuccinate as the final product [163, 164], whereas dimethyl meso tartrate is converted into a racemic mixture of D- and L-a,a -difluorosuccmates [765] (equation 80)... 

This reaction does not involve any of the bonds to the chirality center, and so both the starting alcohol (—) and the product bromide (3-) have the same relative configuration. 

For azomethine ylides and carbonyl ylides, the diastereoselectivity is more complex as the presence of an additional chiral center in the product allows for the formation of four diastereomers. Since the few reactions that are described in this chapter of these dipoles give rise to only one diastereomer, this topic will not be mentioned further here [10]. 

The high enantioselectivity of the exo product opens up a new and readily accessible route to an enantioselective synthesis of interesting isoquinoline alkaloids (Scheme 6.15) [35]. The tricyclic isoxazolidine exo-15b was obtained from the 1,3-dipolar cydoaddition reaction as the pure exo isomer and with 58% ee [34]. As shown in Scheme 6.15 the exo product from the 1,3-dipolar cydoaddition was converted into 17 in two steps without racemization at the chiral center. In addition to the illustrated synthesis, the 6,7-dimethoxy-derived isoxazolidine exo-15b is a very useful precursor for the synthesis of naturally occurring isoquinoline alkaloids [36-40]. 

Hie use of chiral catalysts as an approach to enantiomer icaliy enriched products by means of coppet-mediated substitution reactions is covered in this chapter. Reactions in which a chiral auxiliary resides in the leaving group of the substrate w ill also he dealt with, since these reactions provide direct and efBcient routes to single enantiomers of the desired products. Most studies so far have been concerned with allylic substrates, with a new chiral center being produced in the course of a selec-... 

By treatment of a racemic mixture of an aldehyde or ketone that contains a chiral center—e.g. 2-phenylpropanal 9—with an achiral Grignard reagent, four stereoisomeric products can be obtained the diastereomers 10 and 11 and the respective enantiomer of each. 

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