Chiral auxiliaries amides

Table 6. Amides 13 by Removal of the Chiral Auxiliary from Iron-Acyl Complexes 12 n1 R4 R1...

Chiral Auxiliaries at Ester and Amide Groups a,/MJnsaturated Esters... 

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. 

Using a chiral auxiliary via the amide" or ester" leads to asymmetric induction. 

A number of other types of chiral auxiliaries have been employed in enolate alkylation. Excellent results are obtained using amides of pseudoephedrine. Alkylation occurs anti to the a-oxybenzyl group.93 The reactions involve the Z-enolate and there is likely bridging between the two lithium cations, perhaps by di-(isopropyl)amine.94... 

The enolates of other carbonyl compounds can be used in mixed aldol reactions. Extensive use has been made of the enolates of esters, thiol esters, amides, and imides, including several that serve as chiral auxiliaries. The methods for formation of these enolates are similar to those for ketones. Lithium, boron, titanium, and tin derivatives have all been widely used. The silyl ethers of ester enolates, which are called silyl ketene acetals, show reactivity that is analogous to silyl enol ethers and are covalent equivalents of ester enolates. The silyl thioketene acetal derivatives of thiol esters are also useful. The reactions of these enolate equivalents are discussed in Section 2.1.4. 

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 C(9)-C(14) segment VI was prepared by Steps D-l to D-3. The formation of the vinyl iodide in Step D-3 was difficult and proceeded in only 25-30% yield. The C(15)-C(21) segment VII was synthesized from the common intermediate 17 by Steps E-l to E-6. A DDQ oxidation led to formation of a 1,3-dioxane ring in Step E-l. The A-methoxy amide was converted to an aldehyde by LiAlH4 reduction and the chain was extended to include C(14) and C(15) using a boron enolate of an oxazo-lidinone chiral auxiliary. After reductive removal of the chiral auxiliary, the primary alcohol group was converted to a primary iodide. The overall yield for these steps was about 25%. 

Reagent control This involves the addition of a chiral enolate or allyl metal reagent to an achiral aldehyde. Chiral enolates are most commonly formed through the incorporation of chiral auxiliaries in the form of esters, acyl amides (oxazolines), imides (oxazolidinones) or boron enolates. Chiral allyl metal reagents are also typically joined with chiral ligands. 

As with the above pyrrolidine, proline-type chiral auxiliaries also show different behaviors toward zirconium or lithium enolate mediated aldol reactions. Evans found that lithium enolates derived from prolinol amides exhibit excellent diastereofacial selectivities in alkylation reactions (see Section 2.2.32), while the lithium enolates of proline amides are unsuccessful in aldol condensations. Effective chiral reagents were zirconium enolates, which can be obtained from the corresponding lithium enolates via metal exchange with Cp2ZrCl2. For example, excellent levels of asymmetric induction in the aldol process with synj anti selectivity of 96-98% and diastereofacial selectivity of 50-200 116a can be achieved in the Zr-enolate-mediated aldol reaction (see Scheme 3-10). 

Fairly recently, an increase in the use of allenyl amides bearing chiral auxiliaries could be observed. Many interesting and synthetically useful results can be expected in this area. Sulfur- and selenium-substituted allenes have rarely been employed, although many of their subsequent products would feature unique properties. Hence it should be possible to switch the donor property of a sulfur substituent to an electron-accepting group by various oxidation methods. 

The inter- or intramolecular cyclopropanation of achiral alkenes with enantiome-rically pure diazoacetic esters [1016,1363,1364] or amides [1365,1366] does not usually proceed with high diastereoselectivity. A chiral auxiliary which occasionally gives good results is pantolactone (3-hydroxy-4,4-dimethyltetrahydro-2-furanone) [1016,1367,1368]. 

The pyrrolobenzodiazepine-5,11 -diones II have been utilized in asymmetric syntheses of both the cis- and tra i-decahydro-quinoline alkaloids (Schemes 21 and 22). For example, reduction of 100 with 4.4 equiv. of potassium in the presence of 2 equiv. of t-BuOH, followed by protonation of the resulting enolate with NH4CI at —78 °C gave the cA-fused tetra-hydrobenzene derivative 101.Amide-directed hydrogenation of 101 gave the hexahydrobenzene derivative with diastereo-selectivity greater than 99 1. Removal of the chiral auxiliary and adjustment of the oxidation state provided aldehyde 103 which was efficiently converted to the poison frog alkaloid (+)-pumiliotoxin C. 

Enantiomeric excesses of up to 76% have been obtained for alkyllithium-aldehyde condensations using 3-aminopyrrolidine lithium amides as chiral auxiliaries. Addition of organolithiums to imines has been achieved with up to 89% ee, in the presence of C2-symmetric bis(aziridine) ligands. ... 

Asymmetric Strecker Synthesis of a-Amino Acids via a Crystallization-Induced Asymmetric Transformation Using (/Q-Phenylglycine Amide as Chiral Auxiliary... 

Diastereoselective Slrecker reactions based on (R)-phenylglycine amide as chiral auxiliary are reported. The Strecker reaction is accompanied by an In situ crystallization-induced asymmetric transformation, whereby one diastereomer selecliveiy precipitates and can be isolated in 76-33% yield and dr > gsti. The diastereomeilcaily pure a-amino nitrtie obtained from pivaidehyde (R, = t-Bu, Rj = H) was converted in three steps to (S)-tert-leucine in 73% yieid and >98% ee. 

In summary, (R)-phenylglycine amide 1 is an excellent chiral auxiliary in the asymmetric Strecker reaction with pivaldehyde or 3,4-dimethoxyphenylacetone. Nearly diastereomerically pure amino nitriles can be obtained via a crystallization-induced asymmetric transformation in water or water/methanol. This practical one-pot asymmetric Strecker synthesis of (R,S)-3 in water leads to the straightforward synthesis of (S)-tert-leucine 7. Because (S)-phenylglycine amide is also available, this can be used if the other enantiomer of a target molecule is required. More examples are currently under investigation to extend the scope of this procedure. ... 

To present the take-home message of the current work Present-active In summary, (R)-phenylglycine amide 1 is an excellent chiral auxiliary in the asymmetric Strecker reaction with pivaldehyde or 3,4-dimethoxyphenyl-acetone. (From Boesten et al.. 2001)... 

Diastereoselective Strecker reactions based on (R)-phenylglycine amide as chiral auxiliary are reported. The Strecker reaction is accompanied by an in situ crystallization-induced asymmetric transformation, whereby one diastereomer selectively precipitates and... 

R)-Phenylglycine amide I is an excellent chiral auxiliary in the asymmetric Strecker reaction of pivaldehyde 2. In water at 70 °C, the (R,S)-3 product was isolated in 93% yield and dr > 99/1. Work is underway to convert (R,S)-3 to (S)-tert-leucine and thereby complete the asymmetric Strecker reaction. 

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