Lead tetraacetate compounds

Rickborn and co-workers ° ° isolated the cycloadduct 164 from 4-phenylox-azole through careful manipulation of the experimental conditions (Fig. 3.50). They generated benzyne at 0°C from 1-aminobenzotriazole and lead tetraacetate. Compound 164 was stable at room temperature but, on heating, eliminated benzo-nitrile to give isobenzofuran 162, which could be trapped with A -methylmaleimide to afford a quantitative yield of the tetracyclic derivative 166 as an 88 12 mixture of endo and exo isomers. The cyclic aminal 164 was also sensitive to acid and rearranged to 4-hydroxy-3-phenyl-isoquinoline 165 on exposure to silica gel or a catalytic amount of trifluoroacetic acid. The benzyne cycloadditions were also carried out on 4-(4-nitrophenyl)oxazole and 4-(4-methoxyphenyl)oxazole. A fourfold rate increase was seen for the cycloaddition of the nitrophenyl-substituted oxazole relative to the methoxyphenyl analog, indicating a concerted process with little contribution from a polar intermediate. 

Similatly, silvet(II) picolinate and lead tetraacetate can be used to produce carbonyl compounds. 

Cleavage of an alkenoic acid can be carried out with permanganate, a permanganate—periodate mixture, periodate or with nitric acid, dichromate, ozone, or, if the unsaturation is first converted to a dihydroxy compound, lead tetraacetate (71,73). Oxidative ozonolysis is a process for the manufacture of azelaic acid [123-99-9] and pelargonic acid (74). 

The procedure described here serves to illustrate a new, general method for effecting the < -arylation of g-dicarbonyl compounds by means of an aryllead triacetate under very mild conditions. Although the first synthesis of an aryllead triacetate was reported relatively recently, a wide range of these compounds can now be readily prepared. The most direct route to these compounds is plumbation of an aromatic compound with lead tetraacetate, and in the procedure reported here p-methoxyphenyllead triacetate has been prepared in this way. It may also be obtained by reaction of the diarylmercury with lead tetraacetate, a longer, but more general method of synthesis of aryllead triacetates. 

The first synthesis of p-methoxyphenyllead triacetate by direct plumbation was reported by Harvey and Morman, who obtained the compound in 2418 yield by heating anisole and lead tetraacetate in acetic acid at SO C for 4... 

K. Heusler, unpublished results. 62a. This statement does not apply to the reaction of 6/S-hydroxy steroids, as both the hypoiodite as well as the lead tetraacetate reactions furnish the same 6/S, 19-oxido compounds in high yields. 

Cycloalkoxy radical intermediates are readily generated from a parent alcohol by various methods (e.g., nitrite ester photolysis, hypohalite thermolysis, lead tetraacetate oxidation) (83MI1). Once formed, reactive cycloalkoxy radicals undergo /3-scission to produce a carbonyl compound and a new carbon-centered radical. 

The oxidative cleavage of the central carbon-carbon bond in a vicinal diol 1, by reaction with lead tetraacetate or periodic acid, yields two carbonyl compounds 2 and 3 as products. 

The 1,1-dimetallic compounds, R2C(SnMe3)ZnBr, were oxidized by dry air at —10 to 0°C in the presence of Me3SiCl to give aldehydes or ketones, R2C=0. In a related indirect method, arylthallium bis(trifluoroacetates) (prepared by 12-21) can be converted to phenols by treatment with lead tetraacetate followed by triphenylphosphine, and then dilute NaOH. Diarylthallium trifluoroacetates undergo the same reaction. ... 

Vinylic copper reagents react with CICN to give vinyl cyanides, though BrCN and ICN give the vinylic halide instead." Vinylic cyanides have also been prepared by the reaction between vinylic lithium compounds and phenyl cyanate PhOCN." Alkyl cyanides (RCN) have been prepared, in varying yields, by treatment of sodium trialkylcyanoborates with NaCN and lead tetraacetate." Vinyl bromides reacted with KCN, in the presence of a nickel complex and zinc metal to give the vinyl nitrile. Vinyl triflates react with LiCN, in the presence of a palladium catalyst, to give the vinyl nitrile." ... 

This reaction is most often carried out with R = aryl, so the net result is the same as in 14-17, though the reagent is different. It is used less often than 14-17, but the scope is similar. When R = alkyl, the scope is more limited. Only certain aromatic compounds, particularly benzene rings with two or more nitro groups, and fused ring systems, can be alkylated by this procedure. 1,4-Quinones can be alkylated with diacyl peroxides or with lead tetraacetate (methylation occurs with this reagent). 

When hydrazones are oxidized with HgO, Ag20, Mn02, lead tetraacetate, or certain other oxidizing agents, diazo compounds are obtained ... 

In a related reaction, primary aromatic amines have been oxidized to azo compounds by a variety of oxidizing agents, among them Mn02, lead tetraacetate, O2 and a base, barium permanganate, and sodium perborate in acetic acid, tert Butyl hydroperoxide has been used to oxidize certain primary amines to azoxy compounds. 

Compounds containing carboxyl groups on adjacent carbons (succinic acid derivatives) can be bisdecarboxylated with lead tetraacetate in the presence of O2 263 jjjg reaction is of wide scope. The elimination is stereoselective, but not stereospecific (both meso- and dl- 2,3-diphenylsuccinic acid gave trans- stilbene) a concerted mechanism is thus unlikely. The following mechanism is not inconsistent with the data ... 

Compounds containing geminal carboxyl groups (disubstituted malonic acid derivatives) can also be bisdecarboxylated with lead tetraacetate, gcm-diacetates (acylals) being produced, which are easily hydrolyzable to ketones ... 

Many polyazamacrocycles have been alkylated with chloroacetic acid leading to compounds which contain both amine and carboxylic acid functions, e.g. [63] (Stetter et al., 1981). These compounds are similar to EDTA (ethylenediamine tetraacetate). Although the ring size of this class of macrocycles and the number of N—CH2—COOH groups has been modified... 

Oxidation of oxyberberine (58) with lead tetraacetate effected 13-acetoxyl-ation to give 13-acetoxyoxyberberine (116), which was further oxidized to the 14-alkoxy-8,13-dioxo compounds 117 and 118 (Scheme 25). Reduction of 116 with lithium aluminum hydride followed by sodium borohydride afforded ( )-ophiocarpine (92) (78). 

The exact course of the periodate reaction has not yet been established. That an intermediate complex, compound, or ion is involved has been determined kinetically.28 269 261 262 283-286 The exact structure of this intermediate is still in doubt. The most universally accepted structure is a cyclic ester intermediate propounded by Criegee,27 285 analogous to his cyclic ester intermediate for another agent oxidizing 1,2-glycols, lead tetraacetate. 

Oxidation of one molar proportion with sodium pieriodate produces two equivalents of formic acid, in accordance with the existence of hydroxyl groups attached to four contiguous carbon atoms. This oxidation (and also that carried out with lead tetraacetate) gives an aldehyde, whose semicar-bazone has an analysis corresponding to that of the semicarbazone of an ethyl formyl-methyl-furoate (XII). By oxidation of aldehyde XII with silver oxide in alkaline solution, 2-methyl-3,4-furandicarboxylic acid (XIV) was obtained this was identical with the compound described by Alder and Rickert.20 The identity was confirmed by preparation of the respective dianilides. The acid XIV has also been prepared by the reaction between the sodium salt of ethyl acetoacetate and ethyl bromopyruvate.9... 

The structure of the new product from D-glucosamine has also been confirmed by Muller and Varga,7 who oxidized the compound (obtained by Garda Gonz lez) with lead tetraacetate and isolated ethyl 5-formyl-2-methyl-3-pyrrolecarboxylate (XXII), the melting point and other properties of which agreed with those of the compound described by Fischer and Schubert.24... 

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