1,3-acetoxy transfer

An earlier report [i8y] of the formation of 4a-acetoxy-cholest"5"en-3 One (4) from cholest-5-en-3-one (3) can now be interpreted as a preferential a-face attack upon the enolic 3,5-diene. The stereochemistry of acetoxylation suggests a connection with the sterically-controlled 4 -deprotonation of the A -3-ketone discussed in Chapter 4, section 6, but electrophilic attack at C<4) rather than at C 6> in the neutral enol is abnormal, and probably indicates that acetoxy transfer occurs via a cyclic transition state (3 with the reagent bonded to the C(3)-oxygen substituent. Corey [188] has proposed a mechanism of this type, and suggested that the enol triacetoxy-plumbate cf. 5) may arise by direct reaction between the ketone and the reagent. Supporting such an interpretation, the 3-acetoxy 3,5 diene(6) reacted normally (p. 184) with lead tetraacetate to give the 6j -acetoxy-A -3-ketone 7) [i8g] instead of a 4-acetoxy derivative. 

The extent of branching, of whatever type, is dependent on the polymerization conditions and, in particular, on the solvent and temperature employed and the degree of conversion. Nozakura et at.1 1 found that, during bulk polymerization of VAc, the extent of transfer to polymer increased and the selectivity (for abstraction of a backbone vs an acetoxy hydrogen) decreases with increasing temperature. 

Iridium-catalyzed transfer hydrogenation of aldehyde 73 in the presence of 1,1-dimethylallene promotes tert-prenylation [64] to form the secondary neopentyl alcohol 74. In this process, isopropanol serves as the hydrogen donor, and the isolated iridium complex prepared from [Ir(cod)Cl]2, allyl acetate, m-nitrobenzoic acid, and (S)-SEGPHOS is used as catalyst. Complete levels of catalyst-directed diastereoselectivity are observed. Exposure of neopentyl alcohol 74 to acetic anhydride followed by ozonolysis provides p-acetoxy aldehyde 75. Reductive coupling of aldehyde 75 with allyl acetate under transfer hydrogenation conditions results in the formation of homoallylic alcohol 76. As the stereochemistry of this addition is irrelevant, an achiral iridium complex derived from [Ir(cod)Cl]2, allyl acetate, m-nitrobenzoic acid, and BIPHEP was employed as catalyst (Scheme 5.9). 

The enzyme can also catalyze the transfer of an acetyl group from an N-acetylated hydroxylamine (hydroxamic acid) to form an acetoxy product, i.e., an N to O transacetylation and this pathway does not require acetyl Co-A (12). A-hydroxy-4-acetylaminobiphenyl provides an example of this conversion as shown in Figure 7.7. The significance of this pathway is that it leads to the activation of the hydroxamic acid because acetoxy derivatives of aromatic amines are chemically reactive and many are carcinogens such as the heterocyclic amines formed when meat is heated to a high temperature, e.g., 2-amino-1-mcthyl-6-phenylirnidaz()[4,5-i ]pyri(linc. 

The electron-transfer reactions between the /3-cyclodextrin (/3-CD) N-substituted phenothiazine derivatives and /3-CD.ATPO (4-acetoxy-2,2,6,6-tetramethyl-1-oxopiperidinium hexachloroantimonate) were found to be influenced by the conformations of the phenothiazine derivatives restricted by the /3-CD cavity. N-Phenylphenothiazine (PPT) and A-phenylethylphenothiazine (PEPT), included by /3-CD, can transfer an electron to the /S-CD.ATP complex. No electron transfer was observed between the /3-CD.A-benzylphenothiazine (/3-CD.BPT) complex under the same conditions. The conformation of the /3-CD.BPT complex is such that the oxidation centre was shielded by the /3-CD wall and the substituent. However, electron-transfer reactions between y-CD.BPT and /3-CD.ATP and nitric acid occurred. ... 

A realistic RI5 model is used to estimate the relative probabilities of the formation of various types of short branches in ethylene-vinyl acetate copolymers that are rich in ethylene. Butyl is predicted to be the most common short branch in all of the copolymers examined, although it Is less common in the copolymers than in low-density PE. The major factor responsible for the suppression of the Rq4 backbiting intrachain radical transfer is the increased preference for trans states at the main chain bonds flanking the attachment site for an Isolated acetoxy side chain. 

In Reaction 21a there is no net electron transfer to the metal, and the only product is acetic acid. In Reaction 22a, a one-electron transfer to the metal ion occurs, and the peracetic acid moiety of the complex is transformed into an acetoxy radical which will decompose rapidly to CH3 and CO2. 

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