Allyl acetoxylation

Esters and acetylated hydroxyl groups are completely stable under the experimental conditions, but with ketals 10 29,110,112 yields are generally observed in the thermal reaction. Double bonds do not seem to interfere seriously with the course of the reaction provided that the geometric relationship of the free hydroxyl group to the angular methyl group is not changed drastically. In some cases allylic acetoxylation occurs, e.g., at C-7 of A -steroids. ° Ketones are usually stable (especially under photo-lytic conditions) but occasionally a-acetoxylation has been observed. 

Acetylenedimagnesium bromide, 66, 84, 137 Acyl-alkyl diradical disproportionations, 299 Acyl-alkyl diradical recombination, 296 Alkaline hydrogen peroxide, 10, 12, 20 Alkylation of formyl ketones, 93 Alkylation via enolate anions, 86 17a-Alkynyl steroids from 17-ketones, 67 2a-Al]yl-17jS-hydroxy-5a-androstan-3 -one, 9 5 Allylic acetoxylation, 242 Allylmagnesium bromide, 64 17 -Aminoandrost-5-en-3 -ol, 145 17 a-Aminomethy 1-5 a-androstane-3, 1718-diol, 387... 

Allylic acetoxylation.2 Pd(OAc)2 in HOAc can effect allylic acetoxylation of alkenes, probably via a TT-allylpalladium complex, and only a catalytic amount is required in the presence of a cooxidant such as benzoquinone-Mn02. The reaction is not useful in the case of simple alkenes because of lack of discrimination between the two allylic positions, but this acetoxylation can be regioselective in the case of alicyclic alkenes. 

Scheme 36 Allylic acetoxylation of cyclohexene with cobalt(lll)triacetate.

Allylic acetoxylation of cyclohexene (96) at 80 °C affords 3-acetoxycyclohexene (97) in 67% yield (Scheme 36). It was found that the catalytic double-bond isomerization of 3-phenylpropene proceeds by the action of an electrochemically generated 17-electron Co(II) species [132]. The cobalt(III)-mediated electrooxidative decomposition of chlorinated organics, that is, l,3-dichloro-2-propanol, 2-monochloro-propanol, and so on, has been performed... 

Allylic acetoxylation of alkenes is achieved using acetic acid with sodium acetate as solvent and nucleophile. Cyclohexene gives 1 -acetoxycyclohexene as the... 

ALLYLIC ACETOXYLATION OF CYaOALKENES 2-CYCLOHEPTEN-l-YL ACETATE (2-Cyclohepten-l-o1, acetate)... 

Allylic acetoxylation with palladium(II) salts is well known however, no selective and catalytic conditions have been described for the transformation of an unsubstituted olefin. In the present system use is made of the ability of palladium acetate to give allylic functionalization (most probably via a palladium-x-allyl complex) and to be easily regenerated by a co-oxidant (the combination of benzoquinone-manganese dioxide). In contrast... 

These multicomponent catalyst systems have been employed in a variety of aerobic oxidation reactions [27]. For example, use of the Co(salophen) cocatalyst, 1, enables selective allylic acetoxylation of cyclic alkenes (Eq. 6). Cyclo-hexadiene undergoes diacetoxylation under mild conditions with Co(TPP), 2 (Eq. 7), and terminal alkenes are oxidized to the corresponding methyl ketones with Fe(Pc), 3, as the cocatalyst (Eq. 8). 

The formation of vinyl acetate via the oxidative coupling of ethylene and acetic acid was among the earliest Pd-catalyzed reactions developed (Sect. 2) [19,20]. Subsequent study of this reaction with higher olefins revealed that, in addition to C-2 acetoxylation, allylic acetoxylation occurs to generate products with the acetoxy group at the C-1 and C-3 positions (Scheme 14). The synthetic utihty of these products imderhes the substantial historical interest in these reactions, and both BQ and dioxygen have been used as oxidants. 

Scheme 15 Proposed mechanism for the allylic acetoxylation of cyclohexene...

The mechanistic role of BQ in the allylic acetoxylation of alkenes suggests that it may not be possible to achieve direct dioxygen-coupled turnover. Recently, however, Kaneda and coworkers reported BQ-free conditions for aerobic allylic acetoxylation that feature a solvent mixture of acetic acid and M,M-dimethylacetamide (DMA) and O2 as the sole oxidant for the Pd catalyst (Eq. 55) [209]. The reactions are highly selective for C-1 acetoxylation (C-1 C-3 = 7-45 1). High pressures of O2 (6 atm) are required to achieve these results. 

The results of Kaneda are mechanistically interesting because they reveal that BQ is not required for functionalization of the intermediate jr-allyl Pd species (Scheme 15). In Sect. 3, we outlined the fundamental similarities between BQ and dioxygen in their reactions with Pd . The allylic acetoxylation results described above suggest that similarities also exist between the reactions of BQ and O2 with Pd . Because little is known about the coordination... 

Oxidation with lead tetraacetate is a far less selective process.490,491 Studied mainly in the oxidation of cycloalkenes, it gives stereoisomeric 1,2-diol diacetates, but side reactions (allylic acetoxylation, skeletal rearrangement) often occur. A change in reaction conditions in the oxidation of cyclopentadiene allows the synthesis of different isomeric mono- and diesters.492... 

Pd(H) complexes with strongly electron-withdrawing ligands can insert into the allylic C—H bond (path c) to form directly the Jt-allyl complex via oxidative addi-tion.502,694,697 Pd(OOCCF3)2 in acetic acid, for example, ensures high yields of allylic acetoxylated products.698 The delicate balance between allylic and vinylic acetoxylation was observed to depend on substrate structure, too. For simple terminal alkenes the latter process seems to be the predominant pathway.571... 

Allylic acetoxylation of cyclohexene can be selectively effected by palladium acetate in the presence of Mn02 and p-benzoquinone (bq) (equation 298).640... 

Allylic acetoxylation.1 The combination of r-butyl hydroperoxide and Se02 has been used for allylic hydroxylation of alkenes (8, 64-65), but this system is not useful for oxidation of cycloalkenes. Allylic acetoxylation of cycloalkcnes is possible, but in modest yield, with PdCl2 and AgOAc, which probably form a reactive species such as [PdCl(OAc)] . This system can be used in catalytic amounts in the presence of t-butyl hydroperoxide for a reoxidation step. The yield is improved by addition of TcO, which seems to accelerate the oxidation. The most satisfactory ratios of... 

ALLYLIC ACETOXYLATION Palladium(II) chloride-Silver(I) acetate. 

Scheme 4. Allylic acetoxylation of unsubstituted cycloalkenes (a), 1-phenylcyclohexene (b), and 4-methylcyclohexene (c).

The asymmetric allylic acetoxylation of cycloalkenes has also been reported. In this case, the catalyst is a bimetallic palladium(II) complex bearing a chiral bisox-azoline or a chiral diphosphine (DIOP). The reaction is performed in acetic acid/ sodium acetate under oxygen atmosphere at room temperature. Under these conditions, acetoxylation products of cyclohexene and cydopentene are obtained with 55 % and 78 % ee, respectively, albeit in low yields [39a]. 

ALLYLIC ACETOXYLATION Bromine-Silver acetate. Palladiunli(II) trifluoroacetate. 

Some other reactions involving oxidation of the C—Hg bond have been known for some time, but these are either of limited synthetic appeal or have experienced no significant development in recent years. Thus ozonolysis of the C—Hg bond to form carboxylic acids or ketones falls into the first category, whereas allylic acetoxylation of alkenes by Hg(OAc>2 falls into the second category. Nevertheless, this allylic oxidation (Treibe s reaction) has considerable synthetic utility, and has been reviewed quite recently.5 ... 

Acetoxylation of enol thioethers. The reaction of enol thioethers with lead tetraacetate (1,1 equiv.) in THF for 1 hour followed by addition of BFj etherate (or 5 N KOH-ether) results in allylic acetoxylation. The reaction is considered to involve bisacetoxylation of the double bond. Oxidation of sulfur is not observed. Examples ... 

Oxidation of steroidal alketies. Mercuric acetate (2 eq.) reacts with A -steroids (I) to give as the major product A -15-ones (2) rather than the expected allylic acetates, 16(J-acetoxy-14-enes. The tetrasubstituted bond of A -cholestene is unreactive under the same conditions. A -Cholestene (disubstituted) reacts only slowly to give A -cholestene-3-one in 20 % yield with 70% recovery of the starting material. This unexpected reaction of steroidal trisubstiluted double bonds may proceed through an allylic acetoxylation followed by an oxidation step. 

The yields of allylic methoxylation are only moderate ( 25%) and compare unfavorably with the analogous allylic acetoxylation (described later) [40]. 

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