Epoxides, vinyl acylation

A retrosynthetic analysis of fragment 152 can be completed through cleavage of the C16-C17 bond in enone 155, the projected precursor of epoxide 152. This retrosynthetic maneuver furnishes intermediates 156 and 157 as potential building blocks. In the forward sense, acylation of a vinyl metal species derived from 156 with Weinreb amide 157 could accomplish the construction of enone 155. Iodide 153, on the other hand, can be traced retrosynthetically to the commercially available, optically active building block methyl (S)-(+)-3-hydroxy-2-methyIpropionate (154). 

Reaction in organic solvent can sometimes provide superior selectivity to that observed in aqueous solution. For example, Keeling et al recently produced enantioenriched a-trifluoromethyl-a-tosyloxymethyl epoxide, a key intermediate in the synthetic route to a series of nonsteroidal glucocorticoid receptor agonist drug candidates, through the enan-tioselective acylation of a prochiral triol using the hpase from Burkholderia cepacia in vinyl butyrate and TBME (Scheme 1.59). In contrast, attempts to access the opposite enantiomer by desymmetrization of the 1,3-diester by lipase-catalysed hydrolysis resulted in rapid hydrolysis to triol under a variety of conditions. 

Efficient kinetic resolution of chiral unsaturated secondary alcohols by irreversible enzyme-mediated acylation (with vinyl acetate as acylating agent, a crude preparation of Pseudomonas AK, and hexane as solvent) is possible, provided one relatively large and one small substituent are attached to the carbinol carbon. However, the method can be used to resolve substrates that are not amenable to asymmetric epoxidation (see examples 23, 25, 27, 29, where the double bond is either deactivated by an electron-withdrawing substituent, or is of the propargyl alcohol type). Acylation of the / -enantiomer consistently proceeds faster than that of the 5-enantiomer. An example of an allenic alcohol was also reported248. 

Alkylation of vinyl epoxides. Although Pd(0) catalyzes the rearrangement of vinyl epoxides (9,452-453), alkylation of cyclic or acylic vinyl epoxides with dimethyl malonate under neutral conditions is possible with the same catalyst or with bis[l,2-bis(diphenylphosphino)ethane]palladium. The rearrangement and alkylation proceed with different regio- and stereoselectivity.19... 

Cationic t 3-allyltetracarbonyliron complexes are generated by oxidative addition of allyl iodide to pentacarbonyliron followed by removal of the iodide ligand with AgBF4 under a carbon monoxide atmosphere [35]. Similarly, photolysis of vinyl epoxides or cyclic vinyl sulfites with pentacarbonyliron or nonacarbonyldiiron provides Jt-allyltricarbonyliron lactone complexes. Oxidation with CAN provides by demetallation with concomitant coupling of the iron acyl carbon to one of the termini of the coordinated allyl moiety either [3- or 8-lactones (Scheme 1.12) [36, 37]. In a related procedure, the corresponding Jt-allyltricarbonyliron lactam complexes lead to P- and 8-lactams [37]. 

Lithiation of compound 560 with s-BuLi-TMEDA in THF at —78 °C following an inverse addition protocol provided the anion 561. It reacts with primary alkyl iodides and triflates, silyl chlorides, diphenyl disulfide, epoxides, aldehydes, ketones, imines, acyl chlorides, isocyanates and sulfonyl fluorides to yield the expected compounds 562 (Scheme 152). The transmetallation of compound 561 with ZnBr2 allowed the palladium-catalyzed cross-coupling reaction with aryl and vinyl bromides837. When the reaction was quenched with 1,2-dibromotetrafluoroethane, the corresponding bromide 562 (X = Br) is obtained838. 

The discussion above emphasizes that the allyl-Ni reagents are quite selective for carbon halogen bonds, especially allyl, vinyl, and aryl halides. At the same time, modest reactivity as nucleophiles toward reactive carbonyl derivatives has been reported.Simple aldehydes, the more reactive ketones (such as cyclopentanone and benzoquinone), and certain epoxides will undergo 1,2-addition of the aUyl ligand to the carbonyl group. Esters, amides, and, most remarkably, acyl halides are inert toward the allyl Ni reagents under conditions where the reagents do not decompose thermally (<80 °C or so). 

The vinyl-copper bond is reactive towards electrophiles such as protic acids (entries 2, 3, 4, 8, 9), Br2,12, alkyl iodides, allyl and benzyl bromide, acyl halides, benzaldehyde, enones (entry 1), propargylic esters (entry 5), and epoxides (entry 10). 

The scope of vinyl metals as sources of nucleophilic vinyl groups is very great. As well as the expected electrophiles such as halogens, alkyl and acyl halides, aldehydes and ketones, unsaturated carbonyl compounds and epoxides, they also combine with aryl and alkenyl halides with palladium catalysis. The usual stereochemical course is retention at the vinyl group. It is necessary to decide whether the vinyl metal is reactive enough or whether it must first be transformed into an ate complex. Since most of these vinyl metals can be converted into each other with retention, this is an unusually versatile group of reagents. 

Acylation of the adduct 196 of o-nitrophenylthiol and the epoxide ( )-195 with acetic anhydride or vinyl acetate in THF at room temperature catalysed by the lipase from Pseudomonas cepacia gave better results. Reactions with acetic anhydride are of course not possible in aqueous solution. The reaction took 2 days with Ac/) and 7 days with vinyl acetate but the yields and ee were excellent. At 50% conversion, 100% yield of the acetate product 197 and the other enantiomer of the unreacted alcohol 196 can be isolated.53... 

Cyclic vinyl epoxides are versatile building blocks (Table 11) which have been used in palladium-assisted routes to carbocyclic nucleosides. A formal synthesis of ( )-aris-teromycin101, the carbocyclic analog of adenosine, has been accomplished employing ni-tromethane as the nucleophile which serves as an acyl anion equivalent (Table 11. entry 2). The aldehyde is released by subsequent basic potassium permanganate oxidation. If nitromethane is used diluted in tetrahydrofuran, then a mixture of mono- and bis-alkylated product is formed. Whereas the alkylation of cyclohexenoxide with dimethyl malonate proceeds in a 1,4-crs fashion under palladium(O) catalysis, the 1.2-/ra/i.v-product is formed under basic conditions in the absence of the palladium(O) catalyst. 

Methods of Preparation of Hydrophobically Modified WSPs (HMWSPs). Incorporation of Hydrophobes into WSPs. Water-soluble cellulose derivatives ((hydroxyethyl)cellulose, (hydroxypropyl)cellulose, methylcellulose, etc.) or synthetic polymers containing hydroxyl groups (e.g., poly(vinyl alcohol)) can be reacted with a long-chain alkyl halide (2), acyl halide (2), acid anhydride (6), isocyanate (2), or epoxide (2, 3) under appropriate conditions to form an HMWSP. These reactions are shown in Scheme I. These postmodifications can be done in solution or in hetero-... 

By analogy to the DYKAT reactions with vinyl epoxides, Trost et al. have developed the Pd-eatalysed asymmetric dynamic kinetic allylic amination and acyl migration of vinyl aziridines with benzoyl imido carboxylates. As shown in Scheme 2.51, the process afforded the corresponding protected vicinal diamines in high yields and enantioselectivities of up to 93% ee. This methodology was demonstrated to be a platform for the formal synthesis of (-I- )-balanol and analogues. 

Additions to Enones via the Cuprates. ( -(Trimethyl-silyl)vinyllithium undergoes Michael addition to enones, in good yields, in the presence of copper salts (eq 8). The vinyl group can be oxidized to the epoxide, which is then converted to the acyl group. The overall transformation is the addition of an acyl anion equivalent. Q -(Trimethylsilyl)vinyllithium compares favorably with other acyl anion equivalents, particularly with the vinyl ether analogs which do not add well to hindered enones. 

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