Aldols chiral auxiliary removal

Scheme 5 details the asymmetric synthesis of dimethylhydrazone 14. The synthesis of this fragment commences with an Evans asymmetric aldol condensation between the boron enolate derived from 21 and trans-2-pentenal (20). Syn aldol adduct 29 is obtained in diastereomerically pure form through a process which defines both the relative and absolute stereochemistry of the newly generated stereogenic centers at carbons 29 and 30 (92 % yield). After reductive removal of the chiral auxiliary, selective silylation of the primary alcohol furnishes 30 in 71 % overall yield. The method employed to achieve the reduction of the C-28 carbonyl is interesting and worthy of comment. The reaction between tri-n-butylbor-... 

A nice and convergent approach to both compounds makes use of RCM to form the 5-membered building block 71, which mimics the carbohydrate part of the nucleosides. The necessary diene precursor 69 is readily assembled via Evans aldol chemistry. RCM then affords the ring in almost quantitative yield (69->70), leaving the chiral centers and the free hydroxyl group intact. Removal of the chiral auxiliary by reductive cleavage, attachment of the base by means of jt-allylpalladium chemistry, and a final deprotection step complete these highly efficient syntheses [46]. 

As the t-butyl group can readily be removed upon acidic or basic hydrolysis, this method can also be used for //-hydroxyl acid synthesis. In analogy with allylation reactions, the enolate added preferentially to the Re-face of the aldehydes in aldol reactions. Titanium enolate 66 tolerates elevated temperatures, while the enantioselectivity of the reaction is almost temperature independent. The reaction can be carried out even at room temperature without significant loss of stereoselectivity. We can thus conclude that this reaction has the following notable advantages High enantiomeric excess can be obtained (ee > 90%) the reaction can be carried out at relatively high temperature the chiral auxiliary is readily available and the chiral auxiliary can easily be recovered.44... 

The synthesis of the rare amino acid 3-hydroxy-4-methylproline (8)3 involves an aldol reaction of the oxazoiidinone 5 with methacrolein to provide the a-bromo-0-hydroxy adduct 6. Azide displacement and removal of the chiral auxiliary gives 7. On treatment with dicyclohexylborane, 7 undergoes hydroboration-cycloalkyl-ation to provide, after hydrolysis, the methyl ester hydrochloride (8) of (2S,3S,4S)-3-hydroxy-4-methylproline in >97% de. This cycloalkylation should be a useful route to cyclic amino acids as well as pyrrolidines. 

The chiral iV-propionyl-2-oxazolidinones (37 and 38.) play the role of recyclisable chiral auxiliaries, which can be smoothly removed from the aldol adducts 39 and 40 with aqueous potassium hydroxide in methanol to give the... 

In the above asymmetric aldol reaction, the introduction and the removal of the chiral auxiliary are carried out by simple procedures, and high asymmetric induction is achieved even at ice—bath temperature. However, at least a stoichiometric amount of a chiral auxiliary is required in such a stereo-differentiating reaction (chiral auxiliary is attached to the reactant.). 

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). 

In 1992 Ghosh and co-workers provided the first example of the utility of rigid cis-1 -amino-2-indanol-derived oxazolidinone 36 as the chiral auxiliary in the asymmetric. vv//-aldol reaction.60-61 Aldol condensation of the boron enolate of 37 with various aldehydes proceeded with complete diastereofacial selectivity. Effective removal and recovery of the chiral auxiliary was carried out under mild hydrolysis conditions (Scheme 24.6). As both enantiomers of the chiral auxiliary were readily available, both enantiomers of the. yyn-aldol could be prepared with equal asymmetric induction. 

Ghosh also took advantage of the C—2 hydroxyl moiety of aminoindanols as a handle in the aldol reaction. Chiral sulfonamide 41 was O-acylated to give ester 42. The titanium enolate of ester 42 was formed as a single isomer and added to a solution of aldehyde, precomplexed with titanium tetrachloride, to yield the anft -aldol product 43 in excellent diastereoselectivities.63 One additional advantage of the ester-derived chiral auxiliaries was their ease of removal under mild conditions. Thus, hydrolysis of 43 afforded a ft -a-methyl- 3-hydroxy acid 44 as a pure enantiomer and cis-1-/ -1 o I y I s u I f on a m i do- 2 - i n da n ol was recovered without loss of optical purity (Scheme 24.7).63... 

Fukuyama et al. synthesized the alcohol 39 using Evans s chiral auxiliary in the total synthesis of leustroducsin B (37), a potent colony-stimulating factor inducer via NF-kB activation at the transcription level15 (Scheme 2.In). The asymmetric aldol reaction between 38 and the requisite aldehyde proceeded smoothly to afford 39. Protection of the secondary alcohol as the TES ether and removal of the chiral auxiliary with LiSEt furnished the thioester 40. 

Ghosh et al. utilized an asymmetric. vyn-aldol reaction methodology to synthesize the core structure of saquinavir (90), a protease inhibitor recently approved by the U.S. Food and Drug Administration (FDA) for the treatment of AIDS32 (Scheme 2.1dd). Aldol reaction of the boron enolate of 91 with benzyloxyac-etaldehyde in CH2CI2 at -78° C provided the. vyn-aldol product 92 as a single diastereomer in 88% yield. After removal of the chiral auxiliary and several more manipulations, there was obtained a key intermediate amino alcohol (93), from which saquinavir can be synthesized according to known protocol.33... 

Enantioselective aldol synthesis. The dioxolones formed from (S)- or (R)-l and aromatic aldehydes undergo a diastereoselective condensation with enol silyl ethers. Optically active aldols are obtained by removal of the chiral auxiliary by oxidative decarboxylation with PbfOAcfj. A typical example using the dioxolone (2) formed from (R)-1 and benzaldehyde is shown in equation (I). However, only moderate diastereoselectivity... 

Aldol coupling of chiral acetals. The acetals (2) prepared from an aldehyde and (2R,4R)-pentanediol react with a-silyl ketones orenol silyl ethers in the presence of TiCI, to form aldol ethers 3 and 4 with high diastereoselectivity (>95 5). Removal of the chiral auxiliary usually results in decomposition of the aldol, but can be effected after reduction... 

Phenylalanine-derived oxazolidinone has heen used in O Scheme 52 as a chiral auxiliary for as)rmmetric cross-aldolization (Evans-aldol reactions [277,278,279,280,281,282,283,284, 285]). The 6-deoxy-L-glucose derivative 155 has heen prepared by Crimmins and Long [286] starting with the condensation of acetaldehyde with the chlorotitanium enolate of O-methyl glycolyloxazohdinethione 150. A 5 1 mixture is obtained from which pure 151 is isolated by a single crystallization. After alcohol silylation and subsequent reductive removal of the amide, alcohol 152 is obtained. Swem oxidation of 152 and subsequent Homer-Wadsworth-Emmons olefination provides ene-ester 153. Sharpless asymmetric dihydroxylation provides diol 154 which was then converted into 155 (O Scheme 60) (see also [287]). 

Another example of this methodology has appeared recently from Masamune and coworkers in connection with a total synthesis of bryostatin (equation 67). The salient point here is the demonstrated utility of the thiol ester, prepared directly through stereoselective boron enolate aldol condensation. Notice Aat no further activation or removal of a chiral auxiliary is necessary for this transformation, unlike other related aldol methodology. 

Low temperature irradiation of the glycoside thiohydroxamates (178) in the presence of 2-nitropropene gives clean formation of adducts (179). Conversion of the geminal nitro thioether function to a ketone and removal of the chiral auxiliary yields the free aldol product (180) in >90% enantiomeric excess. Single stranded aminoethylglycine dimers (181) and (182) differ only in whether... 

---