Lead acetate ester synthesis

Consistent with such a proposal is the finding that administering doxorubicin in conjunction with MGd, 1, leads to an enhanced effect in vivo. Thus, an effort was made to attach this active agent to a Gd(III) texaphyrin [88], The resulting synthesis is shown in Scheme 5. It involves protection of one alcohol of MGd as the acetate ester. The other free hydroxyl is then converted to the activated succimidyl carbonate (giving intermediate 16), and then coupled to doxorubicin 17 to give the conjugate 18. 

The synthesis of acetate esters is clearly related to the intracellular levels of acetyl CoA as well as to the availability of fusel alcohols. Fig. 17.22 is a diagrammatic representation of these interrelationships. Any factors which increase the intracellular pool of acetyl CoA will elevate ester production provided that a supply of fusel alcohols (i.e. amino acids, see p. 598) is available. Because acetyl CoA occupies a central position in anabolism, (see Fig. 17.8) any restriction of cell growth will lead to elevated levels of acetate esters. 

Several chapters describe ROP of major classes of monomers such as cyclic ethers, acetals, esters, sulfides, amines, amides, oxazolines, and less common ones, like N-carboxyanhydrides (NCAs) of a-amino acids, leading to polypeptides or ROP of cyclic esters of phosphoric add allowing synthesis of the backbones of DNA. 

One route to o-nitrobenzyl ketones is by acylation of carbon nucleophiles by o-nitrophenylacetyl chloride. This reaction has been applied to such nucleophiles as diethyl malonatc[l], methyl acetoacetate[2], Meldrum s acid[3] and enamines[4]. The procedure given below for ethyl indole-2-acetate is a good example of this methodology. Acylation of u-nitrobenzyl anions, as illustrated by the reaction with diethyl oxalate in the classic Reissert procedure for preparing indolc-2-carboxylate esters[5], is another route to o-nitrobenzyl ketones. The o-nitrophenyl enamines generated in the first step of the Leimgruber-Batcho synthesis (see Section 2.1) are also potential substrates for C-acylation[6,7], Deformylation and reduction leads to 2-sub-stituted indoles. 

In 1972, van Leusen, Hoogenboom and Siderius introduced the utility of TosMIC for the synthesis of azoles (pyrroles, oxazoles, imidazoles, thiazoles, etc.) by delivering a C-N-C fragment to polarized double bonds. In addition to the synthesis of 5-phenyloxazole, they also described reaction of TosMIC with /7-nitro- and /7-chloro-benzaldehyde (3) to provide analogous oxazoles 4 in 91% and 57% yield, respectively. Reaction of TosMIC with acid chlorides, anhydrides, or esters leads to oxazoles in which the tosyl group is retained. For example, reaction of acetic anhydride and TosMIC furnish oxazole 5 in 73% yield. ... 

A cursory inspection of key intermediate 8 (see Scheme 1) reveals that it possesses both vicinal and remote stereochemical relationships. To cope with the stereochemical challenge posed by this intermediate and to enhance overall efficiency, a convergent approach featuring the union of optically active intermediates 18 and 19 was adopted. Scheme 5a illustrates the synthesis of intermediate 18. Thus, oxidative cleavage of the trisubstituted olefin of (/ )-citronellic acid benzyl ester (28) with ozone, followed by oxidative workup with Jones reagent, affords a carboxylic acid which can be oxidatively decarboxylated to 29 with lead tetraacetate and copper(n) acetate. Saponification of the benzyl ester in 29 with potassium hydroxide provides an unsaturated carboxylic acid which undergoes smooth conversion to trans iodolactone 30 on treatment with iodine in acetonitrile at -15 °C (89% yield from 29).24 The diastereoselectivity of the thermodynamically controlled iodolacto-nization reaction is approximately 20 1 in favor of the more stable trans iodolactone 30. 

For the synthesis of 2-519, the amines 2-516 were first treated with AlMe3 in benzene at r.t. and after addition of the enol acetates 2-515, easily accessible from 2-513 and 2-514, heated under reflux. Mechanistic investigations using on-line NMR spectroscopy, reveal that a metalated amide 2-517 is formed first. This then leads to a N-acyliminium ion 2-518 which undergoes an electrophilic substitution. Overall, three new bonds are formed selectively in the domino process, and the alkaloid scaffolds 2-519 are provided in very good yields of 79-89%. Interestingly, use of the keto esters 2-513 instead of 2-515 did not lead to the desired products 2-519. 

Alkylisoselenocyanates 339 are also used in the synthesis of 2-methylidene-l,3-selenazolidine derivatives <06T3344>. Nucleophilic addition of the carbanion derived from malononitrile 347 to 339 leads to an intermediate kcten-A, -acetal 348, which reacts with 2-haloacetate ester and 1,2-dibromoethane to provide l,3-selenazolidin-4-ones 350 and 1,3-selenazolidines 352, respectively. 

The efficiency of the [2 + 2]-cycloadditions of 417 was utilized in a strategy for the synthesis of cephalosporin derivatives that carry an acetone or acetic acid ester group in the 3-position (Scheme 6.88) [175]. Liberated in the presence of 2-(trimethylsilyl-oxy)propene, 417 underwent cycloaddition leading to 435, treatment of which with tetrabutylammonium or hydrogen fluoride furnished the A3-cephalosporin 436 admixed with the A2-isomer. This mixture was converted to pure 436 by an oxidation-reduction sequence. In addition to the trimethylsilylenol ether of acetone, the... 

It is not only the esters of organic acids which combine, in the manner of the ethyl acetoacetate synthesis , with the enolates of ketones and of esters an analogous behaviour is shown by the esters of nitrous and nitric, acids. The process which leads to the formation of isonitroso-and atinitro-compounds yields products fundamentally similar to those already described just as with ethyl acetate the group CO.CHs enters, so here, the NO- and N02-groups are involved, and enolise " exactly as does >O=0 ... 

Silanes can react with acceptor-substituted carbene complexes to yield products resulting from Si-H bond insertion [695,1168-1171]. This reaction has not, however, been extensively used in organic synthesis. Transition metal-catalyzed decomposition of the 2-diazo-2-phenylacetic ester of pantolactone (3-hydroxy-4,4-dimethyltetrahydro-2-furanone) in the presence of dimethyl(phenyl)silane leads to the a-silylester with 80% de (67% yield [991]). Similarly, vinyldiazoacetic esters of pantolactone react with silanes in the presence of rhodium(II) acetate to yield a-silylesters with up to 70% de [956]. 

Treatment of DPT (239) with dinitrogen pentoxide in pure nitric acid leads to the isolation of the nitrate ester (249), an unstable explosive which is highly sensitive to impact and readily undergoes hydrolysis. A low nitration temperature favours the formation of (249) and its presence during the nitrolysis of hexamine is clearly undesirable. The nitrolysis of DPT (239) with one equivalent of pure nitric acid in an excess of acetic anhydride yields 1-acetomethyl-3,5,7-trinitro-l,3,5,7-tetraazacyclooctane (251), a useful starting material for the synthesis of other explosives. ... 

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