Chiral olefins, kinetic resolution

Thought Experiment IV on the Hydroboration of Chiral Olefins with Chiral Dialkylboranes Kinetic Resolution... 

The AE reaction has been applied to a large number of diverse allylic alcohols. Illustration of the synthetic utility of substrates with a primary alcohol is presented by substitution pattern on the olefin and will follow the format used in previous reviews by Sharpless but with more current examples. Epoxidation of substrates bearing a chiral secondary alcohol is presented in the context of a kinetic resolution or a match versus mismatch with the chiral ligand. Epoxidation of substrates bearing a tertiary alcohol is not presented, as this class of substrate reacts extremely slowly. 

Asymmetric Synthesis Using a Chiral Molybdenum Catalyst In olefin metathesis, a double bond is cleaved and a double bond is formed. Thus, a chiral carbon center is not constructed in the reaction. To realize the asymmetric induction by ring-closing metathesis, there are two procedures a kinetic resolution and desym-metrization of symmetric prochiral triene. Various molybdenum complexes are synthesized in order to explore the viabihty of these approaches (Figure 6.2). 

Olefin polymerization using heterogeneous catalysts is a very important reaction and stereochemical aspects have been studied extensively. For a review on this topic see Pino et al. [9], Briefly, the origin of stereoregularity in polyolefins (47) is explained by the chiral nature of the acdve site during polymerization. If the absolute configuration of the first intermediate can be controlled by chiral premodification then we should obtain a non-racemic mixture of R - and "S"-chains. This has indeed been observed e.g. with catalyst M4 for the polymerization (partial kinetic resolution) of racemic 3,7-dimethyl-l-octene (ee 37%) and also for the racemic monomer 46 using Cd-tartate M5. 

Before commencing, the attention of the reader is drawn to the terms enantiofacial selectivity and diastereoselectivity. The usage in this chapter does not conform to the strictest possible definitions of these terms. In particular, enantiofacial selectivity is used with reference to the selection and delivery of oxygen by the epoxidadon catalyst to one face of the olefin in preference to the other. This usage extends to chiral allylic alcohols (primarily the 1-substituted allylic alcohols) when the focus of the discussion is on face selection in the epoxidation process. Diastereoselectivity is used in the discussion of kinetic resolution when the generation of diastereomeric compounds is emphasized. 

Optically active diisopinocamphenylborane can be used to resolve racemic olefins. The reagent adds to one enantiomer, and the other is unchanged. Optical purities on the order of 37-65% are possible. Chiral ally lie alcohols can be resolved with chiral epoxidizing agents derived from tartrate complexes of titanium. One enantiomer is epoxidized and the other is not. Thus, die two alcohol enantiomers can be separated, one as the unsaturated alcohol and one as the epoxy alcohol. Use of die other tartrate isomer reverses die stereoselectivity. Selectivities on die order of >100 are possible with this method. As in any kinetic resolution, however, only one enantiomer can be recovered. The other is converted to a different chiral product. 

It should be noted that the related imine-oxaziridine couple E-F finds application in asymmetric sulfoxidation, which is discussed in Section 10.3. Similarly, chiral oxoammonium ions G enable catalytic stereoselective oxidation of alcohols and thus, e.g., kinetic resolution of racemates. Processes of this type are discussed in Section 10.4. Whereas perhydrates, e.g. of fluorinated ketones, have several applications in oxidation catalysis [5], e.g. for the preparation of epoxides from olefins, it seems that no application of chiral perhydrates in asymmetric synthesis has yet been found. Metal-free oxidation catalysis - achiral or chiral - has, nevertheless, become a very potent method in organic synthesis, and the field is developing rapidly [6]. 

Chiral ketone catalysts of the Yang-type (5a and 5b, see above) and of the Shi-type (10, Scheme 10.2) have been successfully used for kinetic resolution of several racemic olefins, in particular allylic ethers (Scheme 10.4) [28, 29]. Remarkable and synthetically quite useful S values of up to 100 (ketone 5b) and above 100 (ketone 10) were achieved. Epoxidation of the substrates shown in Scheme 10.4 proceeds with good diastereoselectivity. For the cyclic substrates investigated with ketone 10 the trans-epoxides are formed predominantly and cis/trans-ratios were usually better than 20 1 [29]. For the linear substrates shown in Scheme 10.4 epoxidation catalyzed by ketone 5b resulted in the predominant formation of the erythro-epoxides (erythro/threo-ratio usually better than 49 1) [28]. 

A completely analogous kinetic resolution succeeds with the Still-Gennari olefination of Figure 11.20. Here the racemic substrate is a different oc-chiral aldehyde. It carries a sulfon-... 

Olefin metathesis does not generate stereogenic centers, however, the reaction may be employed in the desymmetrization of prochiral (poly)olefins of the kinetic resolution of racemates. In the example depicted in Scheme 17, a trialkene is desymmetrized, and the preference for the cyclization reaction with one of the two symmetry-equivalent C = C double bonds leads to the enantioselective formation of the reaction product, a chiral dihydrofuran. The following principal conclusions can be drawn from this study ... 

Fig. 3.28. Thought experiment IV Reaction of 0.5 equiv of an enantiomerically pure chiral dialkylborane with a racemic chiral olefin to effect a kinetic resolution of the latter.

Fig. 9.20. Still-Gennari olefination of a racemic a-chiral aldehyde with an enantiomerically pure phosphonate as kinetic resolution I—Loss of the unreactive enantiomer ent-B of the aldehyde (R stands for the phenylmenthyl group in the Horner-Wadsworth-Emmons products the naming of the products in this figure is in agreement with the nomenclature of Figures 9.18 and 9.19).

A so far still unsolved problem is the direct enantioselective epoxidation of simple terminal olefins. For example the epoxidation of propylene that was achieved with a 41% ee almost twenty years ago by Strukul and his coworkers using Pt/diphosphine complexes is still unsurpassed. Unfortunately such low ee s are of no practical interest. The problem was circumvented by Jacobsen using hydrolytic kinetic resolution of racemic epoxides (Equation 26) and is practised on a multi 100 kg scale at Chirex. The strategy used is to stereose-lectively open the oxirane ring of a racemic chiral epoxide leaving the other enantiomer intact. Reactions are carried out to a 50% maximum conversion. The catalyst belongs to the metal-salen class described above and can be recycled. The products are separated by fractional distillation. 

Yang s chiral ketones 75 have also been used as catalysts in the kinetic resolution of acyclic secondary allyl silyl ethers <2001JOC4619>. Dioxiranes generated in situ from dehydrocholic acid derivatives 122 and Oxone have been used in the asymmetric epoxidations of cinnamic acid derivatives with product ee s up to 95% <2001TA1113, 2002JOC5802> and unfunctionalized olefins (up to 98% ee) <2006T4482>. 

Chirally modified ruthenium clusters have also been used for a kinetic resolution of enantiomers in the catalytic hydrogenation of non-functiona-lized terpene olefins (Scheme 5) The hydrogenation of a-pinene (IR,5R 27 S,5S 28) leads in principle to the cis- and /rans-pinanes (11 ,25,5/ 29 15,21 , 55 30 IR,2R,5R 31 IS",25,55 32). When a racemic mixture of both a-pinene enantiomers (27 and 28) is hydrogenated in the presence of the (15,25,35,5.R)-isopinocampheyl cluster HRu3(CO)9[//3, //2-NEt-... 

Figure 11.4 Proposed stereomodel for kinetic resolution of chiral aminopentenes with an equatorial approach ofthe olefin.

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