Racemic acylated alcohols

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... 

Resolution of racemic alcohols by acylation (Table 6) is as popular as that by hydrolysis. Because of the simplicity of reactions ia nonaqueous media, acylation routes are often preferred. As ia hydrolytic reactions, selectivity of esterification may depend on the stmcture of the acylatiag agent. Whereas Candida glindracea Upase-catalyzed acylation of racemic-cx-methylhenzyl alcohol [98-85-1] (59) with butyric acid has an enantiomeric value E of 20, acylation with dodecanoic acid increases the E value to 46 (16). Not only acids but also anhydrides are used as acylatiag agents. Pseudomonasfl. Upase (PFL), for example, catalyzed acylation of a-phenethanol [98-85-1] (59) with acetic anhydride ia 42% yield and 92% selectivity (74). 

Figure 6.48 Favored enantiomer in lipase-catalyzed acylations of racemic alcohols containing an organometallic substituent.

Apart from being employed solely as solvents, ILs can also be used as reagent carriers (TSlLs, task-specific ionic liquids). An efficient system that uses ILs as solvents and anchoring/acylating reagents for the CAL B-catalyzed separation of racemic alcohols is shown in Scheme 5.17 [69]. 

Enantioenriched alcohols and amines are valuable building blocks for the synthesis of bioactive compounds. While some of them are available from nature s chiral pool , the large majority is accessible only by asymmetric synthesis or resolution of a racemic mixture. Similarly to DMAP, 64b is readily acylated by acetic anhydride to form a positively charged planar chiral acylpyridinium species [64b-Ac] (Fig. 43). The latter preferentially reacts with one enantiomer of a racemic alcohol by acyl-transfer thereby regenerating the free catalyst. For this type of reaction, the CsPhs-derivatives 64b/d have been found superior. 

Typically the reaction was carried out as follows to a mixture of lipase in the IL were added this racemic alcohol and vinyl acetate as the acyl donor. The resulting mixture was stirred at 35°C and the reaction course was monitored by GC analysis. After the reaction, ether was added to the reaction mixture to form a biphasic layer, and product acetate and unreacted alcohol were extracted with ether quantitatively. The enzyme remained in the IL phase as expected (Fig. 2). Two months later, Kim and co-workers reported similar results and Lozano and Ibora " reported other examples of lipase-catalyzed reaction in June. Further Park and Kazlauskas reported full details of lipase-catalyzed reaction in an IL solvent... 

In the late 1990s, Fuji and Kawabata also set out to develop an efficient catalyst that would promote the enantioselective acylation of racemic alcohols. Their strategy was based on the use of a 4-PPY-derived catalyst that would mimic the induced-fit... 

Although in recent years transesterification processes of racemic alcohols have received major attention, enzymatic acylation of amines for synthetic purposes is also being employed as a conventional tool for the synthesis of chiral amines and amides [31], using CALB as the biocatalyst in the majority of these reactions [31a]. The main difference between enzymatic acylation of alcohols and amines is the use of the corresponding acyl donor, because activated esters which are of utility... 

Kinetic optical resolution of racemic alcohols and carboxylic acids by enzymatic acyl transfer reactions has received enormous attention in recent years56. The enzymes generally employed are commercially available lipases and esterases, preferentially porcine liver esterase (PLE) or porcine pancreatic lipase (PPL). Lipases from microorganisms, such as Candida cylindracea, Rhizopus arrhizus or Chromobacterium viscosum, are also fairly common. A list of suitable enzymes is found in reference 57. Standard procedures are described in reference 58. Some examples of the resolution of racemic alcohols are given39. 

The application of enzymatic acylation for the resolution of racemic alcohols in organic solvent has shown to be an effective method to rapidly synthesize chiral alcohols. The racemic alcohols are treated with the lipase and acylating agent one enantiomer remains unconverted whereas the second enantiomer is esterified and easily separated by distillation (Scheme 7.2). Vinyl acetate or isopropenyl acetate are typical acylating agents, as the generated vinyl alcohol tautomerizes rapidly... 

Scheme 7.2 Resolution of racemic alcohols through enzymatic acylation.

Scheme 7.4 Resolution of racemic alcohol enzymatic acylation.

Scheme 7.7 The acylation of racemic alcohol to yield (S)-acetate, an intermediate for the synthesis of (S)-l 5-deoxyspergualin.

Scheme 7.8 Dynamic kinetic resolution of racemic alcohols by the combination of transition metal catalysis with enzymatic acylation.

Standard solid-phase peptide synthesis requires the first (C-terminal) amino acid to be esterified with a polymeric alcohol. Partial racemization can occur during the esterification of N-protected amino acids with Wang resin or hydroxymethyl polystyrene [200,201]. /V-Fmoc amino acids are particularly problematic because the bases required to catalyze the acylation of alcohols can also lead to deprotection. A comparative study of various esterification methods for the attachment of Fmoc amino acids to Wang resin [202] showed that the highest loadings with minimal racemization can be achieved under Mitsunobu conditions or by activation with 2,6-dichloroben-zoyl chloride (Experimental Procedure 13.5). iV-Fmoc amino acid fluorides in the presence of DMAP also proved suitable for the racemization-free esterification of Wang resin (Entry 1, Table 13.13). The most extensive racemization was observed when DMF or THF was used as solvent, whereas little or no racemization occurred in toluene or DCM [203]. 

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. 

Later studies focused on the planar chiral DMAP derivative 21c as catalyst and use of acetic anhydride as an inexpensive and readily available acyl donor [19]. Under these conditions (2 mol% catalyst loading, r.t.) kinetic resolution of several racemic alcohols could be achieved with selectivity factors up to 52 (Scheme 12.7). As a consequence, enantiomerically highly enriched alcohols (> 95% ee) could be obtained at conversions only slightly above 50%. 

Recent years have seen enormous advances in the field of catalytic asymmetric acylations. Most of the work has been devoted to the kinetic resolution of racemic alcohols. For this application the most efficient catalysts currently available are... 

In principle, oxidative kinetic resolution of racemic alcohols can be achieved by using chiral oxidation catalysts such as TEMPO derivatives or dioxiranes. The selectivity achieved by use of these methods is, however, less than that observed in acylation reactions (Section 12.1). 

Kinetic resolution of racemic alcohols by acylation Few steps from chiral diols... 

Amphoteric compounds such as amino acids can be resolved as acid or amine forms after deriving corresponding esters or N-acyl compounds. Racemic alcohols and amines are also resolved by use of optically active isocyanates, where the alcohols and amines are derived the corresponding diastereomeric urethanes or ureas. 

Csajagi et al. (2008) recently demonstrated the enantioselective acylation of racemic alcohols in a continuous flow bioreactor, using Candida antarctica lipase B (CaLB) 167. Employing a packed-bed reactor, containing 0.40 g of enzyme 167, and pumping a solution of rac-phenyl-1-ethanol 119 (10 mg ml-1) in hexane THF vinyl acetate 168 (2 1 1) at a flow rate of 100 gl min-1 (at 25 °C), the authors found the reactor reached steady state after 30 min of operation. Under the aforementioned conditions, the... 

Racemic l-dimethylaminopropan-2-ol (18) was acylated with propanoyl chloride, and the reaction product was analyzed by gas chromatography (GC). The resultant (R)- and (5)-esters 19 (R1 = COEt) were resolved by GC using an a-cyclodextrin column. Reaction of the racemic alcohol 18 was then carried out in the presence of Novozyme 435 and vinyl propanoate, and the reaction was followed by GC. After 4 hours the reaction was approximately 2% complete and the ee of the propanoate ester 19 (R1 = COEt) was 95.9%. After 88 hours the conversion had reached 50% and the ee was still 95.6%. The remarkable specificity of Novozyme 435 for the (/O-amino alcohol 1 A )-18 was evident because even after 3.5 days reaction time, only a very small amount of the (5)-ester was detected. The reaction could be scaled up thus, 1 kg of the racemic amino alcohol 18 was treated with vinyl propanoate (0.5 equivalents) and Novozyme 435 (3% by weight). After 3 days, both optically active products were isolated by distillation at reduced pressure. The (5)-amino alcohol (.V)-18 was recovered in 45% yield, which compared favorably with a yield of 32% for resolution on a small scale. The (R)-propanoate 19 (R1 = COEt) distilled as a colorless oil in 36% yield — slightly higher than that obtained from the small-scale resolution. The overall recovery was 81% from the scaled up reaction. 

Type I Acylative KR of Racemic Alcohols and Amines 8.2.1.1 Aryl Alkyl sec-Alcohols... 

Reaction of the benzodioxocine 170 with the epoxidation reagent resulted in the epoxide 171, which was then opened with sodium azide in situ to provide trans-racemic azide 172 (Scheme 18) <2004MI265>. Reduction of the azide 172 by hydrogenolysis using Pd on carbon gave trans-racemic amine 173 in 70% yield over three steps. On acylation of the amine with acetic anhydride, the trans-racemic alcohol 174 was formed, which was then oxidized with Dess-Martin periodinane into the unstable dioxocinone 175. 

Enzymatic hydrolysis of meso-substrates to enantiomericaily pure compounds is especially efficacious because the maximum theoretical conversion is 100%. However, racemic chiral alcohols can also be conveniently resolved via en-antioselective esterification" wherein an enzyme mediates acyl transfer to enantiomers of a given alcohol at different rates, albeit with a maximum theoretical conversion of only 50%.625 A practical application of such a kinetic resolution is shown in the PPL-mediated esterification of the racemic alcohol 332.1 [Scheme 4.332]636 and many other examples of equal efficiency are known. 

Lipase B from Candida antarctica (CALB) has been shown to be an excellent enantioselective biocatalyst for the stereo-selective acylation of racemic alcohols [14, 15]. The most often used commercial preparation of CALB is Novozym 435, where the enzyme is immobilized on a macroporous acrylic resin and the matrix presents about 90% of the total mass. 

Acyl Transfer Reactions. (6)-A7-benzoyloxazolidinones have been used as acyl transfer reagents to effect the kinetic resolution of racemic alcohols. The bromomagnesium alkoxides formed from phenyl n-alkyl alcohols selectively attack the exocyclic benzoyl moiety to afford recovered auxiliary and the derived (R)-benzoates in >90% ee and >90% yield (eq 47). The scope of this reaction seems to be limited to this class of substrates as selectivity drops with increasing the steric bulk of the alkyl group. 

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