Racemic amines resolution

Deamination, Transamination. Two kiads of deamination that have been observed are hydrolytic, eg, the conversion of L-tyrosiae to 4-hydroxyphenyUactic acid ia 90% yield (86), and oxidative (12,87,88), eg, isoguanine to xanthine and formycia A to formycia B. Transaminases have been developed as biocatalysts for the synthetic production of chiral amines and the resolution of racemic amines (89). The reaction possibiUties are illustrated for the stereospecific synthesis of (T)-a-phenylethylamine [98-84-0] (ee of 99%) (40) from (41) by an (5)-aminotransferase or by the resolution of the racemic amine (42) by an (R)-aminotransferase. 

Resolution of Racemic Amines and Amino Acids. Acylases (EC3.5.1.14) are the most commonly used enzymes for the resolution of amino acids. Porcine kidney acylase (PKA) and the fungaly3.spet i//us acylase (AA) are commercially available, inexpensive, and stable. They have broad substrate specificity and hydrolyze a wide spectmm of natural and unnatural A/-acyl amino acids, with exceptionally high enantioselectivity in almost all cases. Moreover, theU enantioselectivity is exceptionally good with most substrates. A general paper on this subject has been pubUshed (106) in which the resolution of over 50 A/-acyl amino acids and analogues is described. Also reported are the stabiUties of the enzymes and the effect of different acyl groups on the rate and selectivity of enzymatic hydrolysis. Some of the substrates that are easily resolved on 10—100 g scale are presented in Figure 4 (106). Lipases are also used for the resolution of A/-acylated amino acids but the rates and optical purities are usually low (107). 

Unprotected racemic amines can be resolved by enantioselective acylations with activated esters (110,111). This approach is based on the discovery that enantioselectivity of some enzymes strongly depends on the nature of the reaction medium. For example, the enantioselectivity factor (defined as the ratio of the initial rates for (3)- and (R)-isomers) of subtiHsin in the acylation of CX-methyl-ben zyl amine with tritiuoroethyl butyrate varies from 0.95 in toluene to 7.7 in 3-methyl-3-pentanol (110). The latter solvent has been used for enantioselective resolutions of a number of racemic amines (110). 

S(-)-x-(l-Naphthyl)ethylamine has been prepared by resolution of the racemic amine with camphoric acid in unspecified yield.2,3... 

Table 1.3 Influence ofthe organic solvent on the enantioselectivity of the protease subtilisin in the kinetic resolution ofthe racemic amine (9) (expressed as the ratio ofthe initial rate of acylation of the pure enatiomers, Vs/vr).

Later on the crucial role played by the solvent was enlightened in the protease-catalyzed resolution of racemic amines [26]. As shown in Table 1.3, the ratio of the initial rates of acylation of the (S)- and the (Ji)-enantiomers or racemic a-methyl-benzylamine (9) varied from nearly 1 in toluene to 7.7 in 3-methyl-3-pentanol. Similarly, the same authors found a significant solvent effect for the subtilisin-catalyzed transesterification of racemic 1-phenylethanol (10) using vinyl butyrate as acyl donor (Table 1.4 [27]). 

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... 

Here, we have selected a few representative examples of the enzymatic resolution of esters by aminolysis or ammonolysis reactions. On the other hand, the enzymatic acylation of racemic amines is also of great utility for the preparation of optically pure... 

Another philosophy would be the one-pot resolution of two different nucleophiles, alcohol and amine [39]. An acylated racemic alcohol reacts with a racemic amine in... 

Chiral Recognition. The use of chiral hosts to form diastereomeric inclusion compounds was mentioned above. But in some cases it is possible for a host to form an inclusion compound with one enantiomer of a racemic guest, but not the other. This is caUed chiral recognition. One enantiomer fits into the chiral host cavity, the other does not. More often, both diastereomers are formed, but one forms more rapidly than the other, so that if the guest is removed it is already partially resolved (this is a form of kinetic resolution, see category 6). An example is use of the chiral crown ether (53) partially to resolve the racemic amine salt (54). " When an aqueous solution of 54 was... 

Enzymatic resolutions of racemic amines or aminoalcohols via enantioselective acylation... 

If, according to a modified Horeau method (partial kinetic resolution of a racemate), an optically active carboxylic acid is treated with an excess of racemic amine or alcohol, the configuration of the carboxylic acid can be inferred from the optical rotation of the residual amine or alcohol [48]... 

Chiral amines can also be produced using aminotransferases, either by kinetic resolution of the racemic amine or by asymmetric synthesis from the corresponding prochiral ketone. The reaction involves the transfer of an amino group, a proton and two electrons from a primary amine to a ketone, and proceeds via an intermediate imine adduct. A variety of chiral amines can be obtained with high to very high ee-values. Several transformations have been developed and can be carried out on a 100-kg scale [94]. 

Figure 5.19 Recycling experiments in the kinetic resolution of racemic amine using the sol-gel CaLB immobilizate prepared with 18-crown-6 as an additive. (Reproduced from ref. 30, with permission.)... 

The numerous preparations of mono-, di-, tri-, and hexafluoro derivatives of valine, norvaline, leucine, norleucine, and isoleucine, using classical methods of amino acid chemistry (e.g., amination of an a-bromoacid, " azalactone, Strecker reaction, amidocarbonylation of a trifluoromethyl aldehyde, alkylation of a glycinate anion are not considered here. Pure enantiomers are generally obtained by enzymatic resolution of the racemate, chemical resolution, or asymmetric Strecker reaction. ... 

In general, sulfoximines are accessible by various routes, and most of them involve sulfur oxidation/imination sequences. For example, enantiopure 9 is commonly prepared starting from sulfide 10, which is oxidized with hydrogen peroxide (under acidic conditions) giving sulfoxide 11 (Scheme 2.1.1.1). Subsequent imina-tion of 11 with a mixture of sodium azide and sulfuric acid affords sulfoximine 9 as a racemate. Enantiomer resolution can then be achieved with camphorsul-fonic acid, leading to both enantiomers of 9 with high efficiency [15]. Alternatively, many sulfoximine syntheses start from enantiopure sulfoxides [16, 17], which can be stereospecifically iminated with 0-mesitylenesulfonylhydroxyl-amine (MSH) [18], as shown for the synthesis of sulfoximine (1 )-13 in Scheme 2.I.I.2. 

Alternative synthetic approaches include enantioselective addition of the organometallic reagent to quinoline in the first step of the synthesis [16], the resolution of the racemic amines resulting from simple protonation of anions 1 (Scheme 2.1.5.1, Method C) by diastereomeric salts formation [17] or by enzymatic kinetic resolution [18], and the iridium-catalyzed enantioselective hydrogenation of 2-substituted quinolines [19]. All these methodologies would avoid the need for diastereomer separation later on, and give direct access to enantio-enriched QUINAPHOS derivatives bearing achiral or tropoisomeric diols. Current work in our laboratories is directed to the evaluation of these methods. 

Chiral amines are valuable synthons that dominate agrochemicals and pharmaceutical drug pipelines. Current methods for the preparation of amines are largely based upon resolution, and this is an excellent example of an industrial success. BASF makes a range of chiral amines by acylating racemic amines with proprietary esters, whereby one enantiomer is acylated to the amide, which can be easily separated from the unreacted amine [7]. For example, the resolution of racemic 15 in... 

Scheme 7.9 Resolution of racemic amines by lipase-catalyzed enantioselective amide formation (BASF).

Following an initial resolution step with 0.5 mol equivalents (R)-mandelic acid in TBME, the crystalline product was filtered and tlie waste isomers in the mother liquors (39% ee) were washed with base and then subjected to racemization with the SCRAM catalyst. Upon completion, the catalyst precipitated and was screened, fresh racemic amine was added, and the whole was resolved a second time. The process was repeated several times, giving the results summarized in Table 13.2. 

Resolution of Racemic Amines and Amino Acids. Acvlases (EC 3.5.1.14) are the most commonly used enzymes for the resolution of amino acids. Porcine kidney acylase (PKA) and the fungal Aspergillus acylasc (AA) are commercially available, inexpensive, and stable. Amino alcohols can be resolved by a number of pathways, including hydrolysis, esterification, and transesterification. 

Both (R)- and (S)-amino transferase are available forthe synthesis of enantiomerically pure amines from racemic amines. Degrees of conversion were at or close to 50% for resolutions, and enantioselectivities customarily reached > 99% e.e. for the amine product from both resolutions or syntheses from ketones (Stirling, 1992 Matcham, 1996). The donor for resolutions of amine racemates was usually pyruvate whereas either isopropylamine or 2-aminobutane served as donors for reduction of ketones. The products range from i- and D-amino acids such as i-aminobutyric acid (see Section 7.2.2.6) and i-phosphinothricin (see Section 7.4.2) to amines such as (S)-MOIPA (see Section 7.4.2). 

This chapter covers the kinetic resolution of racemic alcohols by formation of esters and the kinetic resolution of racemic amines by formation of amides [1]. The desymmetrization of meso diols is discussed in Section 13.3. The acyl donors employed are usually either acid chlorides or acid anhydrides. In principle, acylation reactions of this type are equally suitable for resolving or desymmetrizing the acyl donor (e.g. a meso-anhydride or a prochiral ketene). Transformations of the latter type are discussed in Section 13.1, Desymmetrization and Kinetic Resolution of Cyclic Anhydrides, and Section 13.2, Additions to Prochiral Ketenes. 

---