Hydroxylation with lead

The conversion of indoles to oxindoles can be achieved in several ways. Reaction of indoles with a halogenaling agent such as NCS, NBS or pyridin-ium bromide perbromide in hydroxylic solvents leads to oxindoles[l]. The reaction proceeds by nucleophilic addition to a 3-haloindolenium intermediate. 

Perbenzoic acid gave a doubly unsaturated triol monobenzoate. Only two hydroxyl groups could be acetylated, and one was tertiary. The saturated triol reacted with lead tetracetate to give an a glycol. When reacted with chromic acid, it gave a hydroxy lactone. From these observations, Windaus and Gmndmann (11) described the correct stmcture for ergosterol (1). 

Early examples of such branched polysulphides, e.g. Thiokol FA, are believed to possess hydroxyl end groups and are coupled by means of zinc compounds such as the oxide, hydroxide, borate and stearate by a mechanism which is not understood. Later elastomers, e.g. Thiokol ST, have been modified by a restricted reductive cleavage (see below) and this generates thiol (mercaptan) end groups. These may be vulcanised by oxidative coupling as illustrated below with lead peroxide ... 

In opocinchenine the hydroxyl group must, therefore, be in the ortho-position relative to the point of attachment of the benzene ring to the quinoline nucleus. The relative positions of the two ethyl groups are determined by the fact that apocincheninic acid ethyl ether on oxidation with lead peroxide and sulphuric acid gives the lactone of hydroxyopo-cincheninic acid ethyl ether (I), which, on oxidation by sodium hypo-bromite, yields quinolylphenetoledicarboxylic acid (II). 

Rao prepared 2a-methyl-5a-cholestan-2i -ol (5) by reaction of methyl-magnesium iodide with 5a-cholestan-2-one (4). The 2i -configuration of the hydroxyl group was established by converting (5) to the 2a-methyl-2j5,19-epoxide (6) with lead tetraacetate and iodine in boiling benzene. 

A seemingly complex heterocycle which on close examination is in fact a latentiated derivative of a salicylic acid shows antiinflammatory activity. It might be speculated that this compound could quite easily undergo metabolic transformation to a salicylate and that this product is in fact the active drug. Condensation of acid 134 with hydroxyl amine leads to the hydroxamic acid 135. Reaction of... 

Hydroxylation at C-5 or C-l3 has also been successfully achieved by lead tetraacetate oxidation, which was extensively studied in connection with isoquinoline alkaloids by Umezawa s group. (+)-Govanine (96) and (+)-discretine (97) were oxidized with lead tetraacetate in acetic acid to afford 5-acetoxy products 100,101, and 102 via p-quinol acetates (e.g., 99) (Scheme 23)... 

Further transformation included additional hydroxylation steps leading to 2,6-dihydroxyquinoline and a trihydroxyquinoline (probably 2,5,6-trihydroxyquinoline). Shukla [322], working with Pseudomonas sp. identified an alternate pathway, involving additional metabolites, besides the 2-hydroxyquinoline and 8-hydroxycoumarin. These were 2,8-dihydroxyquinoline and 2,3-dihydroxyphenylpropionic acid. Quinoline-adapted cells were also able to transform 2-hydroxyquinoline and 8-hydroxycoumarin without a lag phase, providing additional support for their intermediate role as intermediates in the metabolism of quinoline. 

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... 

Neither has oxidation, with lead tetraacetate, of the sirup obtained by dehydration of the D-galactose condensate VIII so far resulted in isolation of the expected dialdehyde. On the other hand, when the anhydride from the D-glucose condensate (XXXIV) was oxidized with lead tetraacetate, an appreciable amount of dialdehyde (XXXVI) was isolated. This discrepancy in behavior is probably attributable to the trans position of the hydroxyl groups of the anhydride derived from D-galactose as compared with the cis configuration for the anhydride from D-glucose. 

The strong interaction of methanol with the surface hydroxyl groups leads to a methylated surface which is clearly shown by Figure 3. The CP/MAS C-NMR line of 59.9 ppm is attributed to surface methyl groups (10). On a NaGeX zeolite, the amount of these groups was computed from the comparison of the relative amounts of CH3OH and of (CI O obtained from either mass spectrometry data or C-NMR measurements (45). ... 

The allene moiety can also interact electrophilically with NBS or PhSeCl followed by intramolecular attack of the hydroxyl group leading to 3-heteroatom-substituted 2,5-dihydrofurans 362. The chirality in the starting compounds can be efficiently transferred to the 2,5-positions of 2,5-dihydrofurans [167]. 

These results also raise a number of interesting general questions related to the stability of surface species when more than one kind of species is present. For example, OH groups on copper are unstable above 200 K, whereas CuOH-COOH is stable above room temperature hydroxylation of lead by H20(g) is not feasible, whereas PbOH COOH is stable at the same temperature in vacuo. The analogy between the surface hydroxy formate (Fig. 16) and ethylene interaction with CuO is striking. 

A highly modified methyl testosterone derivative also exhibits antiandrogenic activity. One synthesis of this compound involves initial alkylation of methyl testosterone (35) by means of strong base and methyl iodide to afford the 4,4-dimethyl derivative 6. Formylation with alkoxide and methyl formate leads to the 2-hydroxymethyl derivative 37. Reaction of this last with hydroxyl amine leads to formation of an isoxazole ring. There is then obtained azastene (38) . 

Application of the carbonylation reaction to halides with appropriately placed hydroxyl groups leads to lactone formation. In this case, the acylpalladium intermediate is trapped intramolecularly. 

Figure 5 Individual examples of simulated sites of damage induced by 3.2 MeV alpha particles in DNA. In each example, the outer and inner rows represent the sugar-phosphate moieties and the pairs of bases, respectively, with single base pair resolution (dots). An x or H represent energy deposition or reaction of hydroxyl radical leading to induction of a single strand break or base damage. A indicates hit sites that did not lead to strand breaks (SB) or base damage (BD). Nomenclature no strand break (No SB) single strand break (SSB), (SSB ), (2SSB) double strand break (DSB), (DSB+), (DSB + ).

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