Chiral synthetic strategy

Upon removal of the auxiliary, an enantioenriched product could be obtained. The application of chiral auxiliary-based methods to Simmons-Smith cyclopropanation not only provided a useful synthetic strategy, but it also served to substantiate earlier mechanistic hypotheses regarding the directing influence of oxygen-containing functional groups on the zinc reagent [6dj. 

Several elegant synthetic strategies have been devised for biotin (1) this chapter describes one of the total syntheses developed at Hoffmann-La Roche. This insightful synthesis employs a derivative of L-cysteine, a readily available member of the chiral pool,2 as the starting material, and showcases the powerful intramolecular nitrone-olefin [3+2] cycloaddition reaction. 

Applications of peroxide formation are underrepresented in chiral synthetic chemistry, most likely owing to the limited stability of such intermediates. Lipoxygenases, as prototype biocatalysts for such reactions, display rather limited substrate specificity. However, interesting functionalizations at allylic positions of unsaturated fatty acids can be realized in high regio- and stereoselectivity, when the enzymatic oxidation is coupled to a chemical or enzymatic reduction process. While early work focused on derivatives of arachidonic acid chemical modifications to the carboxylate moiety are possible, provided that a sufficiently hydrophilic functionality remained. By means of this strategy, chiral diendiols are accessible after hydroperoxide reduction (Scheme 9.12) [103,104]. 

Polynuclear complexes based on octahedral building blocks may be structurally not well defined because of stereogenic problems [8]. However, clever synthetic strategies have recently been devised to obtain chirally pure species [61-65]. Synthesis and, of course, photophysical and photochemical studies of stereochemically pure metal-based dendrimers are still in their infancy. 

Takahashi and coworkers have used INOC for synthesis of the chiral CD rings paclitaxel, which is an antitumor agent. Synthetic strategy starting from 2-deoxy-D-ribose is demonstrated in Scheme 8.22.110 The precursor of INOC was prepared by 1,2-addition of a,(3-unsaturated ester to ketone. INOC and subsequent reductive cleavage by H2/Raney Ni afford the desired CD ring structure. 

This chapter has introduced the aldol and related allylation reactions of carbonyl compounds, the allylation of imine compounds, and Mannich-type reactions. Double asymmetric synthesis creates two chiral centers in one step and is regarded as one of the most efficient synthetic strategies in organic synthesis. The aldol and related reactions discussed in this chapter are very important reactions in organic synthesis because the reaction products constitute the backbone of many important antibiotics, anticancer drugs, and other bioactive molecules. Indeed, study of the aldol reaction is still actively pursued in order to improve reaction conditions, enhance stereoselectivity, and widen the scope of applicability of this type of reaction. 

Considering the entire synthesis illustrated in the previous section, clearly the construction of such a complicated molecule with all the desired stereogenic centers is highly tedious and demanding work. Therefore, an entirely different conceptual method based on double asymmetric induction was finally developed as a less complex synthetic strategy. A good example is the synthesis of 6-deoxyerythronolide B (28), which bears the same 10 chiral centers as eryth-ronolide A (compound la of the previous section). 

D Acquarica, L, New synthetic strategies for the preparation of novel chiral stationary phases for high-performance liquid chromatography containing natural pool selectors, J. Pharm. Biomed. Anal, 23, 3, 2000. 

Asymmetric allylic oxidation and benzylic oxidation (Kharasch-PSosnovsky reaction) are important synthetic strategies for constructing chiral C—O bonds via C—H bond activation.In the mid-1990s, the asymmetric Kharasch-Sosnovsky reaction was first studied by using chiral C2-symmetric bis(oxazoline)s. " Later various chiral ligands, based mainly on oxazoline derivatives and proline derivatives, were used in such asymmetric oxidation. Although many efforts have been made to improve the enantioselective Kharasch-Sosnovsky oxidation reaction, most cases suffered from low to moderate enantioselectivities or low reactivities. 

Figure II. Some synthetic strategies leading to chiral crown compounds with homotopic faces stalling from chiral piecuisois with C2 symmetry.

Figure 13. Two synthetic strategies leading to chiral crown compounds with heterotopic faces starting from asymmetric precursors. Note that, although the product obtained in (b) has Cj symmetry, the symmetry element does not exchange the environment of the two faces.

Using very similar synthetic strategies, the chiral dimethyl-18-crown-6 derivatives (SiS )-81 and (55)-82 and the chiral tetramethyl-18-crown-6 derivative (5SSS)-83 have been made (12S) in good yields from ethyl (S)-lactate as the chiral synthon. 

Enantiopure epoxides and vicinal diols are important versatile chiral building blocks for pharmaceuticals (Hanson, 1991). Their preparation has much in common and they may also be converted into one another. These chirons may be obtained both by asymmetric synthesis and resolution of racemic mixtures. When planning a synthetic strategy both enzymic and non-enzymic methods have to be taken into account. In recent years there has been considerable advance in non-enzymic methods as mentioned in part 2.1.1. Formation of epoxides and vicinal diols from aromatics is important for the break down of benzene compounds in nature (See part 2.6.5). 

The same synthetic strategy as in the synthesis of planar-chiral ferrocenes was applied to the preparation of rheniumtricarbonyl 14, which has also been studied as a catalyst in aryl transfer reactions [21], Subsequently, this chemistry has been extended, and various catalytic applications of cyrhetrenes 15, 16 (AAPhos), and related derivatives have recently been demonstrated [22]. 

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