Auxiliaries, chiral hydrolysis

Oxo esters are accessible via the diastereoselective 1,4-addition of chiral lithium enamine 11 as Michael donor. The terr-butyl ester of L-valine reacts with a / -oxo ester to form a chiral enamine which on deprotonation with lithium diisopropylamide results in the highly chelated enolate 11. Subsequent 1,4-addition to 2-(arylmethylene) or 2-alkylidene-l,3-propanedioates at — 78 °C, followed by removal of the auxiliary by hydrolysis and decarboxylation of the Michael adducts, affords optically active -substituted <5-oxo esters232 (for a related synthesis of 1,5-diesters, see Section 1.5.2.4.2.2.1.). In the same manner, <5-oxo esters with contiguous quaternary and tertiary carbon centers with virtually complete induced (> 99%) and excellent simple diastereoselectivities (d.r. 93 7 to 99.5 0.5) may be obtained 233 234. 

One of the early syntheses of orlistat (1) by Hoffmann-La Roche utilized the Mukaiyama aldol reaction as the key convergent step. Therefore, in the presence of TiCU, aldehyde 7 was condensed with ketene silyl acetal 8 containing a chiral auxiliary to assemble ester 9 as the major diastereomer in a 3 1 ratio. After removal of the amino alcohol chiral auxiliary via hydrolysis, the a-hydroxyl acid 10 was converted to P-lactone 11 through the intermediacy of the mixed anhydride. The benzyl ether on 11 was unmasked via hydrogenation and the (5)-7V-formylleucine side-chain was installed using the Mitsunobu conditions to fashion orlistat (1). 

L-Amino acids 11 are available by the same methodology using tri-0-pivaloyl-a-D-arabinosylamine 10 as the chiral auxiliary [19b], The stereoselectivity L D 7-10 1 is slightly lower compared to that observed for the syntheses of / -aminonitriles 8 with galactosyl imines 7. The free a-amino acid is released from the auxiliary by hydrolysis with HCI in formic acid. 

As will be described below, self-reproduction of chirality can be accomplished through alkylations of endocyclic as well as exocyclic enolates. It generally entails (i) production of a ring containing a temporary, auxiliary chiral center by derivatization of an optically active a-hydroxy or a-amino ester (ii) formation of an enolate by deprotonation at the original asymmetric a-carbon atom (iii) use of intramolecular chirality transfer to control the stereochemistry of alkylation of the enolate and (iv) generation of the chiral a-alkylated ester by hydrolysis. 

The result, upon removal of the chiral auxiliary by hydrolysis, favors selection of the E-enantiomer in this case. There are several examples of use of Method 4 in the chemical literature,6 but the technique does suffer from one disadvantage— one reaction is required to add the chiral auxiliary and another to remove it. 

Butadiene telomerizes with chiral cyclohexanone-derived enamines under substrate control with (5)-2-(methoxymethyl)pyrrolidine (SMP) or its a,a-dimethyl analog as chiral auxiliary12. After removal of the auxiliary by hydrolysis, 2-[( )-2,7-octadienyl]cyclohexanone (6) is obtained in 57 % yield with 72 % ee (R = H) or in 60 % yield with 92 % ee (R = CH3). Cyclopen-tanones, cycloheptanones and cyclooctanones can be similarly converted. 

Chiral oxazolines developed by Albert I. Meyers and coworkers have been employed as activating groups and/or chiral auxiliaries in nucleophilic addition and substitution reactions that lead to the asymmetric construction of carbon-carbon bonds. For example, metalation of chiral oxazoline 1 followed by alkylation and hydrolysis affords enantioenriched carboxylic acid 2. Enantioenriched dihydronaphthalenes are produced via addition of alkyllithium reagents to 1-naphthyloxazoline 3 followed by alkylation of the resulting anion with an alkyl halide to give 4, which is subjected to reductive cleavage of the oxazoline moiety to yield aldehyde 5. Chiral oxazolines have also found numerous applications as ligands in asymmetric catalysis these applications have been recently reviewed, and are not discussed in this chapter. ... 

Cleavage of the chiral auxiliary is effected in a three-step procedure commencing with quatemization of the nitrogen with methyl fluorosulfonate, methyl trlfluoromethanesulfonate, or trimethyloxonium tetrafluoroborate. Reduction of the corresponding iminium salt 19 with NaBH4 and acidic hydrolysis of the resulting product affords substituted aldehyde 5 without epimerization of either stereocenter. 

Cleavage of the chiral auxiliary is carried out by exhaustive methylation. followed by hydrolysis, which leads to x-methoxy aldehydes 7 that can be further oxidized to the corresponding oc-methoxy acids. 

Compared to the lithium enolates of l and 5, the higher stereoselectivity obtained by the Mukaiyama variation is, in general, accompanied by reduced chemical yields. The chiral alcoholic moieties of the esters 3 and 7 can be removed either by reduction with lithium aluminum hydride (after protection of the earbinol group) or by aqueous alkaline hydrolysis with lithium hydroxide to afford the corresponding carboxylic acid. In both cases, the chiral auxiliary reagent can be recovered. 

R)- and (,S )-1.1,2-Triphenyl-l,2-ethancdiol which are reliable and useful chiral auxiliary groups (see Section 1.3.4.2.2.3.) also perform ami-sclcctive aldol additions with remarkable induced stereoselectivity72. The (/7)-diastercomer, readily available from (7 )-methyl mandelate (2-hy-droxy-2-phcnylaeetate) and phenylmagnesium bromide in a 71 % yield, is esterified to give the chiral propanoate which is converted into the O-silyl protected ester by deprotonation, silylation, and subsequent hydrolysis. When the protected ester is deprotonated with lithium cyclohexyliso-propylamide, transmetalated by the addition of dichloro(dicyclopentadienyl)zirconium, and finally reacted with aldehydes, predominantly twm -diastereomers 15 result. For different aldehydes, the ratio of 15 to the total amount of the syn-diastereomers is between 88 12 and 98 2 while the chemical yields are 71 -90%. Furthermore, high induced stereoselectivity is obtained the diastereomeric ratios of ami-15/anti-16 arc between 95 5 and >98 2. 

Alkaline hydrolysis of the crude adduct formed with benzaldehyde, followed by treatment with diazomethane and column chromatography, affords methyl (2R,3S)-3-hydroxy-2-methyl-3-phenylpropanoate in 96% ee. Reduction of the crude products formed in the reactions with 2-inethylpropanal and 2,2-dimethylpropanal leads to the corresponding 1,3-diols with >96% ee. In both the hydrolysis and the reduction procedures, the chiral auxiliary reagent, 1,1,2-triphenyl-1,2-ethanediol, can be recovered and reused72. 

In another approach, a glucose-derived titanium enolate is used in order to accomplish stereoselective aldol additions. Again the chiral information lies in the metallic portion of the enolate. Thus, the lithiated /m-butyl acetate is transmetalated with chloro(cyclopentadienyl)bis(l,2 5,6-di-0-isopropylidene- -D-glucofuranos-3-0-yl)titanium (see Section I.3.4.2.2.I. and 1.3.4.2.2.2.). The titanium enolate 5 is reacted in situ with aldehydes to provide, after hydrolysis, /i-hydroxy-carboxylic acids with 90 95% ee and the chiral auxiliary reagent can be recovered76. 

After addition reactions, the chiral auxiliary is recovered in an unracemized state as the diol, from hydrolysis of the adducts 6/7. 

Alkaline hydrolysis of the adducts 6 and 7, which is fairly mild in the case of the imide adducts, liberates 3-hydroxycarboxylic acids 8 or ent-8 and simultaneously regenerates the chiral auxiliary reagent. Furthermore, both enantiomers of the 3-hydroxycarboxylic acid are available in almost optically pure form depending on which reagent is chosen as the starting material. 

Acetylsultam 15 is also used for stereoselective syntheses of a-unsubstituted /1-hydroxy-carboxylic acids. Thus, conversion of 15 into the silyl-A/O-ketene acetal 16 and subsequent titanium(IV) chloride mediated addition to aldehydes lead to the predominant formation of the diastereomers 17. After separation of the minor diastereomer by flash chromatography, alkaline hydrolysis delivers /f-hydroxycarboxylic acids 18, with liberation of the chiral auxiliary reagent 1919. 

Chiral imines derived from 1-phenylethanone and (I. Sj-exo-l, 7,7-trimethyIbicyclo-[2.2.1]heptan-2-amine [(S)-isobornylamine], (.S>1-phenylethanamine or (R)-l-(1-naphthyl) ethanamine are transformed into the corresponding (vinylamino)dichloroboranes (e.g., 3) by treatment with trichloroborane and triethylamine in dichloromethane. Reaction of the chiral boron azaenolates with aromatic aldehydes at 25 "C, and subsequent acidic hydrolysis, furnishes aldol adducts with enantiomeric excesses in the range of 2.5 to 47.7%. Significantly lower asymmetric inductions are obtained from additions of the corresponding lithium and magnesium azaenolates. Best results arc achieved using (.S )-isobornylamine as the chiral auxiliary 3. 

Auxiliary-controlled Streeker syntheses have so far only been carried out with amines serving as the chiral components. In the first asymmetric Streeker synthesis a solution of sodium cyanide, ( — )-(S)-a-methylbeuzylamine and its hydrochloride in water was mixed with a methanolie solution of acetaldehyde and stirred for five days. Hydrolysis of the resulting amino nitrile and subsequent hydrogenolysis furnished L-alanine with 90% optical purity 38-39-85. 

Amidoalkylation of silyl enol ethers with /V-acyliiiiiiiium ions containing camphanoyl-derived acyl functions (see Appendix) as the chiral auxiliary leads to optically active 2-substituted piperidine derivatives with moderate to high diastereoselectivity, depending on the chiral auxiliary and the cnol ether82 99. The auxiliary is removed by hydrolysis with base or acid. 

In y-alkoxyfuranones the acetal functionality is ideally suited for the introduction of a chiral auxiliary simultaneously high 71-face selectivity may be obtained due to the relatively rigid structure that is present. With ( + )- or (—(-menthol as auxiliaries it is possible to obtain both (5S)- or (5/ )-y-menthyloxy-2(5//)-furanones in an enantiomerically pure form293. When the auxiliary acts as a bulky substituent, as in the case with the 1-menthyloxy group, the addition of enolates occurs trans to the y-alkoxy substituent. The chiral auxiliary is readily removed by hydrolysis and various optically active lactones, protected amino acids and hydroxy acids are accessible in this way294-29s-400. 

The addition reactions of alkyllithium-lithium bromide complexes to a-trimethylsilyl vinyl sulfones that have as a chiral auxiliary a y-mono-thioacetal moiety derived from ( + )-camphor are highly diastereoselective. A transition state that involves chelation of the organolithium reagent to the oxygen of the thioacetal moiety has been invoked. The adducts are readily converted via hydrolysis, to chiral a-substituted aldehydes22. 

As shown in scheme 1, (S)-amide 2 (ref. 4) obtained from ethyl ester of (S)-proline, chiral auxiliary and 2-substituted-2-propenoic acids 1 are bromolactonized with N-bromosuccinimide (NBS)-DMF, followed by hydrolysis with 6N-HC1 to afford (S)-4. The results are summarized in Table 1. 

The highly ordered cyclic TS of the D-A reaction permits design of diastereo-or enantioselective reactions. (See Section 2.4 of Part A to review the principles of diastereoselectivity and enantioselectivity.) One way to achieve this is to install a chiral auxiliary.80 The cycloaddition proceeds to give two diastereomeric products that can be separated and purified. Because of the lower temperature required and the greater stereoselectivity observed in Lewis acid-catalyzed reactions, the best diastereoselectivity is observed in catalyzed reactions. Several chiral auxiliaries that are capable of high levels of diastereoselectivity have been developed. Chiral esters and amides of acrylic acid are particularly useful because the auxiliary can be recovered by hydrolysis of the purified adduct to give the enantiomerically pure carboxylic acid. Early examples involved acryloyl esters of chiral alcohols, including lactates and mandelates. Esters of the lactone of 2,4-dihydroxy-3,3-dimethylbutanoic acid (pantolactone) have also proven useful. 

The adduct cyclized to a lactol mixture that was oxidized by TPAP-NMMO to give the corresponding lactones in an 8 1 ratio (86% yield). Hydrolysis in the presence of H202 gave the P-D lactone and recovered chiral auxiliary. 

Nitroalkenes with Chiral Auxiliaries The use of carbohydrates as chiral auxiliary in Diels-Alder reactions for the stereoselective preparation of carbocyclic and heterocyclic chiral rings is well documented.48 For example, D-manno-nitroalkene reacts with 2,3-dimethyl-1,3-butadiene to give a 65 35 mixture of adducts, as shown in Eq. 8.29. The configurations at C-4 and C-5 have been determined to be (4R,5R) and (45,55), respectively. Hydrolysis of the product followed by degradative oxidation of the sugar side chains leads to enantiomerically... 

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