Synthetic transformation products

The efficiency of a synthetic transformation is normally expressed as a percent yield or percentage of the theo retical yield Theoretical yield IS the amount of prod uct that could be formed if the reaction proceeded to completion and did not lead to any products other than those given in the equation... 

The reaction proceeds in good yield (86%) and the product is a useful one in fur ther synthetic transformations of the type to be described in Section 21 7... 

In 1991, the relatively old and small synthetic fuel production faciHties at Sasol One began a transformation to a higher value chemical production facihty (38). This move came as a result of declining economics for synthetic fuel production from synthesis gas at this location. The new faciHties installed in this conversion will expand production of high value Arge waxes and paraffins to 123,000 t/yr in 1993. Also, a new faciHty for production of 240,00 t/yr of ammonia will be added. The complex will continue to produce ethylene and process feedstock from other Sasol plants to produce alcohols and higher phenols. 

Asymmetric Diels-Alder reactions using a dienophile containing a chiral auxiliary were developed more than 20 years ago. Although the auxiliary-based Diels-Alder reaction is still important, it has two drawbacks - additional steps are necessary, first to introduce the chiral auxiliary into the starting material, and then to remove it after the reaction. At least an equimolar amount of the chiral auxiliary is, moreover, necessary. After the discovery that Lewis acids catalyze the Diels-Alder reaction, the introduction of chirality into such catalysts has been investigated. The Diels-Alder reaction utilizing a chiral Lewis acid is truly a practical synthetic transformation, not only because the products obtained are synthetically useful, but also because a catalytic amount of the chiral component can, in theory, produce a huge amount of the chiral product. 

Few methodologies have either the diversity of synthetic transformations or the high level of product selectivity as catalytic reactions with the intermediate involvement of metal carbenes [ 1-5]. They provide synthetic opportunities that are clearly demonstrated in the preparation of the antidepressant sertraline (1)... 

In each of the synthetic transformations shown, the reagents are appropriate for the desired transformation but the reaction would not succeed as written. Suggest a protective group strategy that would permit each transformation to be carried out to give the desired product. 

Several synthetic transformations that are parts of total syntheses of natural products are summarized by retrosynthetic outlines. For each retrosynthetic transform suggest a reagent or short reaction sequence that could accomplish the forward synthetic conversion. The proposed route should be diastereoselective but need not be enantioselective. 

Nitrogen dioxide (NO ) reacts with a wide variety of functional groups and it is the reagent of choice for a number of synthetic transformations. For example, the selective oxidation of sulfide to sulfoxide by NO forms the basis for the commercial production of dimethyl sulfoxide (from dimethyl sulfide) via a catalytic procedure (see below).250 Some representative examples of oxidative transformations carried out with NO are presented in Chart 8. 

Synthetic transformations of the products of the intramolecular bis-silylation have been examined. The five-membered ring products derived from homopropargylic alcohols were hydrogenated in a stereoselective manner (Scheme ll).90 Oxidation of the products under the Tamao oxidation conditions (H202/F /base)96 leads to the stereoselective synthesis of 1,2,4-triols. This method can be complementary to the one involving intramolecular bis-silylation of homoallylic alcohols (vide infra). 

The direct high yield synthesis of oxaspiropentanes from almost any type of aldehyde or ketone represents a particularly useful transformation because of the high reactivity of such compounds. This approach proves to be exceptionally simple. The DMSO reaction mixture can be directly extracted with pentane or hexane, the hydrocarbon solvent removed and the product isolated by distillation or crystallization. Since diphenyl sulfide is the only by-product extracted with the oxaspiropentane, the mixture can normally be used for most further synthetic transformations. Table 2 summarizes some of the oxaspiropentanes prepared by this method. 

Reformatsky product (46). Treatment of 46 with methanol and an acid ion-exchange resin afforded the methyl glycoside 47a, the product of partial hydrolysis (47b), and the 3,8-anhydro sugar 48. Synthetic transformations were performed on these products (52). 

A key aspect of any synthesis strategy on a polymeric support is the linkage element, which acts as a tether to the polymeric support. Ideally, the linker should be stable to all reaction conditions used in a synthesis sequence and should be cleaved quantitatively under conditions that do not degrade the desired target molecule [6]. In this overview the different kinds of linkers and the synthetic transformations that can be used on polymeric supports will be presented. At the end, synthetic strategies for the synthesis of heterocycles and natural products will be mentioned. 

The synthetic potential of the imidoylated product is noteworthy since some manipulations of the C-Te bond are useful for synthetic transformation. 

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