Enantioselective Reaction Conditions

Various chiral catalysts have been explored in the search for enantioselective ami-noalkylation. Zhou and coworkers used hA-oxazolines with W-tosyl-C-arylimines. The best results were obtained with a dibenzyl h T-oxazoline in the presence 

Deng and coworkers used A/-arenesulfonyl imines and employed modified cinchona alkaloids as the chiral agent. The best catalysts were thioiuea derivative of quinidine and quinine. These conditimis proved to be applicable to C-alkyl as well as C-aryl imines. The products can be desulfonylated and then isolated as the Cbz derivatives without loss of stereochemical integrity [310]. 

Excellent enantioselectivity has also been obtained using 3,3 -6 s-(l-naphthyl) BINOL-phosphoric acids [311]. A -Tosyl imines of aryl aldehydes were also examined using a binaphthyl Pd(II) carbene complex as the catalyst. Enantioselectivity in the 50-75% range was obtained [312]. Imines formed from ot-phenylethylamine and ethyl 3,3,3-trifluoropyruvate give adducts with 85-97% de in the presence of TEA [313]. The chiral auxiliary can be removed by hydrogenolysis. 

An enantioselective version of the amidoalkylation reaction has been achieved using or-acetamidostyrene and chiral phosphoric acids. The highest ee was observed with sterically demanding acids. The reaction failed when the indole nitrogen was methylated, suggesting that the hydrogen bond is an important part of the reactive complex [314]. 

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Silyl ethers serve as preeursors of nucleophiles and liberate a nucleophilic alkoxide by desilylation with a chloride anion generated from CCI4 under the reaction conditions described before[124]. Rapid intramolecular stereoselective reaction of an alcohol with a vinyloxirane has been observed in dichloro-methane when an alkoxide is generated by desilylation of the silyl ether 340 with TBAF. The cis- and tru/u-pyranopyran systems 341 and 342 can be prepared selectively from the trans- and c/.y-epoxides 340, respectively. The reaction is applicable to the preparation of 1,2-diol systems[209]. The method is useful for the enantioselective synthesis of the AB ring fragment of gambier-toxin[210]. Similarly, tributyltin alkoxides as nucleophiles are used for the preparation of allyl alkyl ethers[211]. 

Efficient enantioselective asymmetric hydrogenation of prochiral ketones and olefins has been accompHshed under mild reaction conditions at low (0.01— 0.001 mol %) catalyst concentrations using rhodium catalysts containing chiral ligands (140,141). Practical synthesis of several optically active natural... 

There are a number of powerful synthetic reactions which join two trigonal carbons to form a CC single bond in a stereocontrolled way under proper reaction conditions. Included in this group are the aldol, Michael, Claisen rearrangement, ene and metalloallyl-carbonyl addition reactions. The corresponding transforms are powerfully stereosimplifying, especially when rendered enantioselective as well as diastereoselective by the use of chiral controller groups. Some examples are listed in Chart 20. 

The main strategy for catalytic enantioselective cycloaddition reactions of carbonyl compounds is the use of a chiral Lewis acid catalyst. This approach is probably the most efficient and economic way to effect an enantioselective reaction, because it allows the direct formation of chiral compounds from achiral substrates under mild conditions and requires a sub-stoichiometric amount of chiral material. 

Enantioselectivities were found to change sharply depending upon the reaction conditions including catalyst structure, reaction temperature, solvent, and additives. Some representative examples of such selectivity dependence are listed in Scheme 7.42. The thiol adduct was formed with 79% ee (81% yield) when the reaction was catalyzed by the J ,J -DBFOX/Ph aqua nickel(II) complex at room temperature in dichloromethane. Reactions using either the anhydrous complex or the aqua complex with MS 4 A gave a racemic adduct, however, indicating that the aqua complex should be more favored than the anhydrous complex in thiol conjugate additions. Slow addition of thiophenol to the dichloromethane solution of 3-crotonoyl-2-oxazolidinone was ineffective for enantioselectivity. Enantioselectivity was dramatically lowered and reversed to -17% ee in the reaction at -78 °C. A similar tendency was observed in the reactions in diethyl ether and THF. For example, a satisfactory enantioselectivity (80% ee) was observed in the reaction in THF at room temperature, while the selectivity almost disappeared (7% ee) at 0°C. 

The diastereo- and enantioselectivity are clearly dependent on a number of factors, including the reaction conditions, sulfide structure, and nature of the ylide. 

Jacobsen subsequently reported a practical and efficient method for promoting the highly enantioselective addition of TMSN3 to meso-epoxides (Scheme 7.3) [4]. The chiral (salen)Cl-Cl catalyst 2 is available commercially and is bench-stable. Other practical advantages of the system include the mild reaction conditions, tolerance of some Lewis basic functional groups, catalyst recyclability (up to 10 times at 1 mol% with no loss in activity or enantioselectivity), and amenability to use under solvent-free conditions. Song later demonstrated that the reaction could be performed in room temperature ionic liquids, such as l-butyl-3-methylimidazo-lium salts. Extraction of the product mixture with hexane allowed catalyst recycling and product isolation without recourse to distillation (Scheme 7.4) [5]. 

Subsequent to the development of the (salen)Cr-catalyzed desymmetrization of meso-epoxides with azide (Scheme 7.3), Jacobsen discovered that the analogous (salen)Co(n) complex 6 promoted the enantioselective addition of benzoic acids to meso-epoxides to afford valuable monoprotected C2-symmetric diols (Scheme 7.15) [26], Under the reaction conditions, complex 6 served as a precatalyst for the (salen) Co(iii)-OBz complex, which was fonned in situ by aerobic oxidation. While the enantioselectivity was moderate for certain substrates, the high crystallinity of the products allowed access to enantiopure materials by simple recrystallization. 

A very efficient and universal method has been developed for the production of optically pue L- and D-amino adds. The prindple is based on the enantioselective hydrolysis of D,L-amino add amides. The stable D,L-amino add amides are effidently prepared under mild reaction conditions starting from simple raw materials (Figure A8.2). Thus reaction of an aldehyde with hydrogen cyanide in ammonia (Strecker reaction) gives rise to the formation of the amino nitrile. The aminonitrile is converted in a high yield to the D,L-amino add amide under alkaline conditions in the presence of a catalytic amount of acetone. The resolution step is accomplished with permeabilised whole cells of Pseudomonas putida ATCC 12633. A nearly 100% stereoselectivity in hydrolysing only the L-amino add amide is combined with a very broad substrate spedfidty. 

Biocatalysts usually require mild reaction conditions for an optimal activity (physiologic temperature and pH) and, in general, they show high activity, chemo- and enantioselectivity. Furthermore, when using enzymes, many functional group protections and/or activations can be avoided, allowing shorter synthetic transformations. The use of enzymes is therefore very attractive from an environmental and economic point of view. 

Racemization of amines is difficult to achieve and usually requires harsh reaction conditions. Reetz et al. developed the first example of DKR of amines using palladium on carbon for the racemization and CALB for the enzymatic resolution [35]. This combination required long reaction times (8 days) to obtain 64% yield in the DKR of 1-phenylethylamine. More recently, Backvall et al. synthesized a novel Shvo-type ruthenium complex (S) that in combination with CALB made it possible to perform DKR of a variety of primary amines with excellent yields and enantioselectivities (Figure 4.13) [36]. 

Although the aminolysis of esters to amides is auseful synthetic operation, usually it presents some disadvantages in terms of drastic reaction conditions, long reaction times or strong alkali metal as catalyst, which are usually not compatible with other functional groups in the molecule [6]. For this reason, enzymatic aminolysis of carboxylic acid derivatives offers a clean and ecological way for the preparation of different kind of amines and amides in a regio-, chemo-, and enantioselective manner. 

Irimescu and Kato have recently described an interesting example of enzymatic KR in ionic liquids instead of organic solvents (Scheme 7.4) [12]. The resolution with CALB is based on the fact that the reaction equilibrium was shifted toward the amide synthesis by the removal of water under reduced pressure. Nonsolvent systems have been also employed in this enantioselective amidation processes, reacting racemic amines with aliphatic acids. The best reaction conditions for the conversion of acids to amides was observed using CALB at 90 °C under vacuum. Meanwhile, no... 

In recent years, a great variety of primary chiral amines have been obtained in enantiomerically pure form through this methodology. A representative example is the KR of some 2-phenylcycloalkanamines that has been performed by means of aminolysis reactions catalyzed by lipases (Scheme 7.17) [34]. Kazlauskas rule has been followed in all cases. The size of the cycle and the stereochemistry of the chiral centers of the amines had a strong influence on both the enantiomeric ratio and the reaction rate of these aminolysis processes. CALB showed excellent enantioselec-tivities toward frans-2-phenylcyclohexanamine in a variety of reaction conditions ( >150), but the reaction was markedly slower and occurred with very poor enantioselectivity with the cis-isomer, whereas Candida antarctica lipase A (GALA) was the best catalyst for the acylation of cis-2-phenylcyclohexanamine ( = 34) and frans-2-phenylcyclopropanamine ( =7). Resolution of both cis- and frans-2-phenyl-cyclopentanamine was efficiently catalyzed by CALB obtaining all stereoisomers with high enantiomeric excess. 

Scheme 7a-c. Switch in enantioselectivity with the reaction conditions... 

The structure I might form a five-membered cyclic structure on Pd metal and then the structure would be adsorbed at the less bulky side of the molecule. On the other hand, structure II might not form such a cyclic structure because of the steric hindrance. The difference in the ease of formation of the cyclic complex between structure I and II might be an important factor why structure I is a major conformation in the reaction. It is assumed that the adsorpted state of reactants as structure I or II may be influenced by the reaction conditions such as the Pd metal size, resulting in the different enantioselectivity. 

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