Heterocyclic compounds silylation

The combination of silyl enol ethers and fluoride ion provides more reactive anions to give alkylated nitro compounds in good yields after oxidation with DDQ, as shown in Eq. 9.22.36 This process provides a new method for synthesis of indoles and oxyindoles (see Chapter 10, Synthesis of Heterocyclic Compounds). 

This type of nucleoside includes numerous simple derivatives of heterocyclic compounds. Only a few examples are given. Condensation of the chloro-methyl ethers 1053 with silylated 5-fluorouracil gave the two mono- and one disubsituted derivatives 1054,1055, and 1056, respectively (86MI3). 

Less well-established cycloaddition chemistry has also found application in the synthesis of heterocyclic compounds in recent years. An example is the intramolecular cycloaddition of silyl nitronates that has been employed by Ishikawa and Saito to afford 136 in their synthesis of amino polyols (Scheme 14) <2003OL3875>. 

The reaction of nitroarenes with silyl end ethers and ketene silyl acetals in MeCNATiF with 1 equiv. of TASF, followed by in situ oxidation with Br2 or DDQ, provides an easy route to a-nitroaryl carbonyl compounds (Scheme l).12 The use of these compounds as reagents for the synthesis of arylacetic acids, propionic acids, indoles, 2-indolinones and other heterocyclic compounds has recently been described.88... 

Another class of heterocyclic compounds are silyl-substituted triazoles which can be obtained by the addition of TMS-azide 14) and manifold substituted acetylenes 1, 35, 350 (Scheme 50)33,209 2ll Those in the first step resulting l-TMS-4-phenyl (3Ji)-, l-TMS-4,5-bis(methoxycarbonyl)- 352) and l-TMS-4-alkyl-l, 2,3-triazole 353) are then hydrolyzed to form 4-phenyl- 354)-, 4,5-bis(methoxycarbonyl)- 355), 4-alkyl-l,2,3-triazole 356). 

The double silylation of unsaturated organic compounds catalyzed by group 10 metals is a convenient synthetic route to disilacyclic compounds. Nickel and platinum complexes, in particular, are excellent catalysts for the transformation of disilanes. Cyclic bis(silyl)metal complexes2,3 have been implicated as key intermediates in the metal-catalyzed double silylation of alkynes, alkenes, and aldehydes however, the intermediates have not been isolated due to their instability. We now describe (i) the isolation of the reactive intermediates cyclic bis(silyl)metal compounds (1) with bulky o-carborane unit 4 (ii) the generation of a new class of heterocyclic compounds (4-5) by the stoichiometric reaction of the intermediates with a variety of substrates such as an alkyne, dione, and nitrile 4 and (iii) the facile double silylation of alkenes and alkynes (10,12-14) catalyzed by the intermediate under mild conditions.5... 

Another class of heterocyclic compounds are silyl-substituted triazoles which can be obtained by the addition of TMS-azide (14) and manifold substituted acetylenes 1, 35, 350 (Scheme 50) yj ose in the first step resulting l-TMS-4-phenyl... 

Intramolecular photocyclization is a useful method for the preparation of cyclic and heterocyclic compounds. Mariano and his coworkers have developed intramolecular PET reactions of iminium salts having silyl groups and used this process to prepare selected natural products. Intramolecular electron transfer from the or-ganosilicon group to the iminium salt generates the diradical cation. The intramolecular radical coupling of the l.n-diradical intermediate formed via desilylation gives iV-heterocyclic products. 

In 1987, a new class of phosphorus heterocyclic compounds was developed by Cowley and coworkers, incorporating keto groups within various phosphorus-containing rings [37]. At the time, only the synthesis of these compounds was reported via reaction between a silylated phosphane and an acyl chloride (Scheme 12.7). More recently, we developed the diketophosphepin as a multifunctional material involving the seven-membered phosphorus ring (28a-d Figure 12.19)... 

Birkofer, L., Richter, P. and Ritter, A. (1960), Silicon—organic compounds. VI. Activation of N-containing heterocycles by silylation. Chem. Ber., 93,2804. 

Replacement of heterocyclic rings in nucleosides by ring systems which do not occur in nature represents another approach to compounds which may have activity against viral and neoplastic diseases. One of the early successes in this category involves replacement of a pyrimidine ring by a triazine. The synthesis starts with a now classical glycosidation of a heterocycle as its silylated derivative (146) with a protected halosugar (145), in this case a derivative of arabinose... 

Deprotection of 2,2-disubstituted-l,3-dithiolanes to give carbonyl compounds can be achieved using Oxone with KBr in aq. MeCN <06TL8559> and a review of silylated heterocycles as formyl anion equivalents includes reference to 64 <06CC4881>. A method for transformation of propargylic dithiolanes 43 into tetrasubstituted furans has been reported <06SL1209> and Michael addition of enolates to the chiral dithiolane dioxide 65 takes place... 

Main Rearrangements of BENA In previous Sections (3.5.4.1. and 3.5.4.2.), a-hydroxy oximes (503) and their bis-silyl derivatives (504) were considered as undesired by-products, formed in the synthesis and chemical transformations of BENA. The aim was to minimize the amount of these impurities. On the other hand, oximes (503) are convenient precursors of various useful products, such as p-amino alcohols (530), amino acids (531), a-hydroxycarbonyl compounds (532) and various heterocyclic systems (533). 

The ruthenium carbene catalysts 1 developed by Grubbs are distinguished by an exceptional tolerance towards polar functional groups [3]. Although generalizations are difficult and further experimental data are necessary in order to obtain a fully comprehensive picture, some trends may be deduced from the literature reports. Thus, many examples indicate that ethers, silyl ethers, acetals, esters, amides, carbamates, sulfonamides, silanes and various heterocyclic entities do not disturb. Moreover, ketones and even aldehyde functions are compatible, in contrast to reactions catalyzed by the molybdenum alkylidene complex 24 which is known to react with these groups under certain conditions [26]. Even unprotected alcohols and free carboxylic acids seem to be tolerated by 1. It should also be emphasized that the sensitivity of 1 toward the substitution pattern of alkenes outlined above usually leaves pre-existing di-, tri- and tetrasubstituted double bonds in the substrates unaffected. A nice example that illustrates many of these features is the clean dimerization of FK-506 45 to compound 46 reported by Schreiber et al. (Scheme 12) [27]. 

Further, a large number of examples with simple alkyl substituents [168, 171, 176-184], cyclic alkanes [185], aryl substituents [177, 186-192], olefmic substituents [78, 177, 193-196], deuterated compounds [172], thioether groups [171], ester groups [197], orthoesters [198, 199], acetals [168, 182, 200-204], silyl-protected alcohols [198, 205-211], aldehydes [212], different heterocycles [213-217], alkyl halides [218, 219] and aryl halides [192, 220-223] have been reported. A representative example is the reaction of 92, possessing a free hydroxyl group, an acetal and a propargylic ether, to 93 [224] (Scheme 1.40). 

Different strategies all including nucleophilic addition to acceptor-substituted allenes have been used for the synthesis of cyclic compounds, mostly heterocycles. Thus, it is obvious to release a nucleophile already existing within the allenic compound in a protected form. For example, treatment of silyl ethers 197 with tetrabu-tylammonium fluoride (TBAF) leads to the intermediates 198, which yield the dihy-drofurans 199 by nucleophilic addition (Scheme 7.32) [251]. 

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