Enantiomeric additive

A multigram preparation of a useful chiral building block was developed, using the Beckmann rearrangement as a key synthetic step (equation 115) °. The enantiomeric addition of thiophenol to a chalcone 313, catalysed by (+)-cinchonine, provided the chiral enantiomeric carbonyl compound 314. The Beckmann rearrangement of its oxime 315 gives the anilide of (R)-(- -)-3-phenyl-3-phenylsulfanylpropanoic acid 316. Alcoholysis produced the expected enantiomerically pure ethyl ester 317. 

In the Sharpless epoxidation of divinylmethanols only one of four possible stereoisomers is selectively formed. In this special case the diastereotopic face selectivity of the Shaipless reagent may result in diastereomeric by-products rather than the enantiomeric one, e.g., for the L -(-(-)-DIPT-catalyzed epoxidation of (E)-a-(l-propenyl)cyclohexaneraethanol to [S(S)-, [R(S)-, [S(R)- and [R(R)-trans]-arate constants is 971 19 6 4 (see above S.L. Schreiber, 1987). This effect may strongly enhance the e.e. in addition to the kinetic resolution effect mentioned above, which finally reduces further the amount of the enantiomer formed. 

Chiral additives, however, do pose some unique problems. Many chiral agents are expensive or are not commercially available, and therefore, must be synthesized. The presence of the chiral additive in the bulk Hquid phase may also interfere with detection or recovery of the analytes. Finally, the presence of enantiomeric impurity in the chiral additive may add analytical complications (10). 

The primary disadvantage of the conjugate addition approach is the necessity of performing two chiral operations (resolution or asymmetric synthesis) ia order to obtain exclusively the stereochemicaHy desired end product. However, the advent of enzymatic resolutions and stereoselective reduciag agents has resulted ia new methods to efficiently produce chiral enones and CO-chain synthons, respectively (see Enzymes, industrial Enzymes in ORGANIC synthesis). Eor example, treatment of the racemic hydroxy enone (70) with commercially available porciae pancreatic Hpase (PPL) ia vinyl acetate gave a separable mixture of (5)-hydroxyenone (71) and (R)-acetate (72) with enantiomeric excess (ee) of 90% or better (204). 

The reaction is characteristic of the usual Michael addition of hydroperoxide anion, yielding enantiomeric excesses up to 45%. 

An asymmetric synthesis of estrone begins with an asymmetric Michael addition of lithium enolate (178) to the scalemic sulfoxide (179). Direct treatment of the cmde Michael adduct with y /i7-chloroperbenzoic acid to oxidize the sulfoxide to a sulfone, followed by reductive removal of the bromine affords (180, X = a and PH R = H) in over 90% yield. Similarly to the conversion of (175) to (176), base-catalyzed epimerization of (180) produces an 85% isolated yield of (181, X = /5H R = H). C8 and C14 of (181) have the same relative and absolute stereochemistry as that of the naturally occurring steroids. Methylation of (181) provides (182). A (CH2)2CuLi-induced reductive cleavage of sulfone (182) followed by stereoselective alkylation of the resultant enolate with an allyl bromide yields (183). Ozonolysis of (183) produces (184) (wherein the aldehydric oxygen is by isopropyUdene) in 68% yield. Compound (184) is the optically active form of Ziegler s intermediate (176), and is converted to (+)-estrone in 6.3% overall yield and >95% enantiomeric excess (200). 

Cyanohydrin Synthesis. Another synthetically useful enzyme that catalyzes carbon—carbon bond formation is oxynitnlase (EC 4.1.2.10). This enzyme catalyzes the addition of cyanides to various aldehydes that may come either in the form of hydrogen cyanide or acetone cyanohydrin (152—158) (Fig. 7). The reaction constitutes a convenient route for the preparation of a-hydroxy acids and P-amino alcohols. Acetone cyanohydrin [75-86-5] can also be used as the cyanide carrier, and is considered to be superior since it does not involve hazardous gaseous HCN and also virtually eliminates the spontaneous nonenzymatic reaction. (R)-oxynitrilase accepts aromatic (97a,b), straight- (97c,e), and branched-chain aUphatic aldehydes, converting them to (R)-cyanohydrins in very good yields and high enantiomeric purity (Table 10). 

Figure 2.24, Determination of the enantiomeric excess of 1-phenylethanol [30, 0.1 mmol in 0.3 ml CDCI3, 25 °C] by addition of the chiral praseodymium chelate 29b (0.1 mmol), (a, b) H NMR spectra (400 MHz), (a) without and (b) with the shift reagent 29b. (c, d) C NMR spectra (100 MHz), (c) without and (d) with the shift reagent 29b. In the C NMR spectrum (d) only the C-a atoms of enantiomers 30R and 30S are resolved. The H and C signals of the phenyl residues are not shifted these are not shown for reasons of space. The evaluation of the integrals gives 73 % R and 27 % S, i.e. an enantiomeric excess (ee) of 46 %...

When enantiomerically pure fni/is-2-acetoxycyclohexyl tosylate is solvolyzed, tiie product is racemic /mn -diacetate. This is consistent with the proposed mechanism, since the acetoxonium intennediate is achiral and can only give rise to racemic material. Additional evidence for diis interpretation comes from the isolation of a cyclic ortho ester when the solvolysis is carried out in ethanol. In this solvent the acetoxonium ion is captured by the solvent. 

Addition of p-tert-butylthiophenol 178 to the racemic furanone 168 in dry toluene, and in the presence of quinidine as a chiral catalyst, provided (/ )-168 together with the Michael adduct 179. The enantiomeric excess of the recovered furanone (R)-168 was determined via the addition of (/)-Q -methylbenzylamine This amine addition showed complete diastereofacial control to give the adduct 180 in quantitative yield (Scheme 50) (94T4775). 

The use of chiral dipolarophiles, such as the nitrile oxide additions to chiral furanones, have received much interest. The cycloaddition of various 1,3-dipolar reagents to the enantiomeric ally pure furanones 170 and 227 showed excellent diastereofacial control by the menthyloxy substituent, especially in nitrone and nitrile oxide additions (cf. Table II) (88TL5317). 

Other examples were tested and the results are summarized in Table 5.7 [24]. The reactions always proceeded smoothly to afford the corresponding piperidine derivatives in high yields with high enantiomeric excess. In addition, reverse enantio-... 

Diastereoselective conjugate additions to chital Michael acceptors in which the part initially heating the chital information is removable ii.e., a chital auxiliary) provides a means to synthesize enantiomerlcally pure conjugate adducts. Chital auxiliaries iduould ideally he readily available in both enantiomeric fornts. Tliey should... 

Non-functionalized alkenes 6, with an isolated carbon-carbon double bond lacking an additional coordination site, can be epoxidized with high enantiomeric excess by applying the Jacobsen-Katsuki epoxidation procedure using optically active manganese(iii) complexes ... 

---