Enolate anions, boron

Trifluoromethylation of Enolate Anions with a Suitable Combination of Boron Lewis Acids (94JOC5692)... 

Various enolate anions were trifluoromethylated regioselectively in good yields by a combination of 5-salt 17 with boron 59 (Eqs. 33-35). 

The stereoselectivity of the trifluoromethylation varied with the bulkiness of the boron reagent used. Thus, with enolate anion 64, the product ratio of the thermodynamically less stable )8-CF3 isomer 66 versus the more stable a-CF3 isomer 65 increased with the bulkiness in the order 59 < 60 < 61 (Eq. 37). This was explained by the conformation of the intermediate complexes. 

Silyl enol ethers react with aldehydes in the presence of chiral boranes or other additives " to give aldols with good asymmetric induction (see the Mukaiyama aldol reaction in 16-35). Chiral boron enolates have been used. Since both new stereogenic centers are formed enantioselectively, this kind of process is called double asymmetric synthesis Where both the enolate derivative and substrate were achiral, carrying out the reaction in the presence of an optically active boron compound ° or a diamine coordinated with a tin compound ° gives the aldol product with excellent enantioselectivity for one stereoisomer. Formation of the magnesium enolate anion of a chiral amide, adds to aldehydes to give the alcohol enantioselectively. 

Complementary to the acylation of enolate anions is the acid-catalyzed acylation of the corresponding enols, where the regiochemistry of acylation can vary from that observed in base-catalyzed reactions. Although the reaction has been studied extensively in simple systems, it has not been widely used in the synthesis of complex molecules. The catalysts most frequently employed are boron trifluoride, aluminum chloride and some proton acids, and acid anhydrides are the most frequently used acylating agents. Reaction is thought to involve electrophilic attack on the enol of the ketone by a Lewis acid complex of the anhydride (Scheme 58). In the presence of a proton acid, the enol ester is probably the reactive nucleophile. In either case, the first formed 1,3-dicarbonyl compound is converted into its borofluoride complex, which may be decomposed to give the 3-d>ketone, sometimes isolated as its copper complex. 

In order to improve the stereoselectivity of the aldol process even further, metal salts of enolate anions other than those bearing lithium have been examined. For example, both magnesium and boron enolates have been prepared. Magnesium enolates are very much like lithium enolates in their stereoselectivity, while boron enolates, where there are relatively short metal-oxygen bonds, give improved selectivity. For the boron enolates, the (Z)-enolate is generally more stable than its E)-isomer, and erythro- or 5yn-products are developed. 

Trifluoromethylation of Potassium Enolate. Trifluoromethylation of potassium enolate of cyclohexanone )flelds Q -(trifluoromethyl)cyclohexanone in the presence of 2-phenyl-1,3,2-benzodioxaborole (eq 23). The boron compound complex and enolate anion increase the reactivity. 

The aldol reactions introduced thus far have been performed under basic conditions where enolate species are involved as the reactive intermediate. In contrast to the commonly accepted carbon-anion chemistry, Mukaiyama developed another practical method in which enol species can be used as the key intermediates. He is the first chemist to successfully demonstrate that acid-catalyzed aldol reactions using Lewis acid (such as TiCU) and silyl enol ether as a stable enol equivalent can work as well.17 Furthermore, he developed the boron tri-fluoromethane sulfonate (triflate)-mediated aldol reactions via the formation of formyl enol ethers. 

The influence of the classical anomeric effect and quasi-anomeric effect on the reactivity of various radicals has been probed. The isomer distribution for the deu-teriation of radical (48) was found to be selective whereas allylation was non-selective (Scheme 37). The results were explained by invoking a later transition state in the allylation, thus increasing the significance of thermodynamic control in the later reactions. Radical addition to a range of o -(arylsulfonyl)enones has been reported to give unexpected Pummerer rearrangement products (49) (Scheme 38).A mechanism has been postulated proceeding via the boron enolate followed by elimination of EtaBO anion. 

The search for endothelin antagonists as potential compounds for treating cardiovascular disease was noted in Chapter 5 (see atrasentan). A composed with a considerably simpler structure incorporates a pyrimidine ring in the side chain. Condensation of benzophenone (94) with ethyl chloro-acetate and sodium methoxide initially proceeds to addition of the enolate from the acetate to the benzophenone carbonyl. The aUcoxide anion on the first-formed quaternary carbon then displaces chlorine on the acetate to leave behind the oxirane in the observed product (95). Methanolysis of the epoxide in the product in the presence of boron triflor-ide leads to the ether-alcohol (96). Reaction of this with the pyrimidine (97) in the presence of base leads to displacement of the methanesulfonyl group by the aUcoxide from 96. Saponification of the ester group in that product gives the corresponding acid, ambrisentan (98). " ... 

The substrate arachidonic aeid, whieh often leads to formation of inflammatory prostaglandins, is stored in tissues as one of a number of phospholipids these compounds, as the name indicates, comprise complex phosphate-containing esters. The antiinflammatory corticosteroids inhibit the action of the enzyme, phospholipase A2, that frees arachidonic acid. The many undesired effects of those steroids has led to the search for non-steroidal inhibitors of that enzyme. A highly substituted indole derivative has shown good activity as a phospholipase A2 inhibitor. Alkylation of the anion from treatment of indole (32) with benzyl chloride affords the corresponding A-benzylated derivative (33). The methyl ether at the 4 position is then cleaved by means of boron tribromide to yield 34. Alkylation of the enolate from reaction of the phenol with sodium hydride with tert-butylbromoacetate affords the corresponding... 

The isolation of the initial aldol products from the condensation of the enolates of carbene complexes and carbonyl compounds is possible if the carbonyl compound is pretreated with a Lewis acid. As indicated in equation (9), the scope of the aldol reaction can also be extended to ketones and enolizable aldehydes by this procedure. The condensations with ketones were most successful when boron trifluoride etherate was employed, and for aldehydes, the Lewis acid of choice is titanium tetrachloride. The carbonyl compound is pretreated with a stoichiometric amount of the Lewis acid and to this is added a solution of the anion generated from the caibene complex. An excess of the carbonyl-Lewis acid complex (2-10 equiv.) is employed however, above 2 equiv. only small improvements in the overall yield are realized. 

Tylonolide hemiacetal (33), the aglycone of the antibiotic tylosin, possesses an anti 14-hydroxymethyl-15-acyloxy stereochemistry conveniently contained in 26, which may be viewed as the western half of 33. In order to prepare the eastern half of 33, an aldol reaction leading to the desired syn stereochemistry at C-3 and C-4 is exploited. The reaction of achiral aldehyde 27 with the S-boron enolate 28 proceeds with the expected diastereofacial selectivity to provide, in a combined yield of 80% after O-silylation, a separable mixture of 29 (derived from the / -enantiomer of 27) and 30 (from the S-enantiomer of 27). Subsequent functional group transformation of 30 ultimately leads to the a-(TMS)methylketone 31. The anion of 31, generated with lithium hexamethylsilazide in THF at — 78 °C, undergoes a Peterson condensation with 26 to afford in 60% yield the seco-diC d 32. Treatment of 32 with 70% acetic acid at 85 °C for one hour affords 33 in 60% yield. The attractive feature of this... 

These boron enolates can be considered as chiral nucleophiles wherein chirality observed in the products of the aldol reactions arises from the chiral auxiliary mandelic acid. An alternative approach to the diastereo- and enantioselective carbon-carbon bond forming reaction is to react an achiral anion precursor with an electrophilic equivalent containing a chiral auxiliary derived from mandelic acid. 

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