Alkoxy cyclization

Selective activation of alkyne functions of enynes to give products either of alkoxy-cyclization or of exo- and endo-skeletal rearrangement can be achieved by using alkynophilic cationic gold(I) complexes. The endocyclic cyclization catalysed by gold(I) proceeds via a mechanism different from those known for Pd(II), Hg(II), or Rh(I) catalysts.118... 

Anomalous Fischer cyclizations are observed with certain c-substituted aryl-hydrazones, especially 2-alkoxy derivatives[l]. The products which are formed can generally be accounted for by an intermediate which w ould be formed by (ip50-substitution during the sigmatropic rearrangement step. Nucleophiles from the reaction medium, e.g. Cl or the solvent, are introduced at the 5-and/or 6-position of the indole ring. Even carbon nucleophiles, e.g. ethyl acetoacelate, can be incorporated if added to the reaction solution[2]. The use of 2-tosyloxy or 2-trifluoromethanesulfonyloxy derivatives has been found to avoid this complication and has proved useful in the preparation of 7-oxygen-ated indoles[3]. 

Isoxazolidinones have been prepared by the cyclization of ethyl 3-O-hydroxyl-aminopropionate and by the cyclization of a-chloropropionhydroxamic acid (62HQ17)1, p. 7). 3-Isoxazolidinones can also be prepared by the hydrolysis of 3-alkoxy- or 3-amino-2-isoxazolines or 2-isoxazolinium salts (Scheme 159) (74BSF1651, 62G501). 

The Gould-Jacobs reaction is a sequence of the following reactions (1) condensation of an arylamine 1 with either alkoxy methylenemalonic ester or acyl malonic ester 2 providing the anilidomethylenemalonic ester 3 (2) cyclization of 3 to the 4-hydroxy-3-carboalkoxyquinoline 4 (3) saponification to form acid 5, and (4) decarboxylation to give the 4-hydroxyquinoline 6. All steps of this process will be described herein with emphasis on the formation of intermediates like 3 and 4. 

The mercaptals obtained by the acid catalyzed reaction of J3-ketoesters, e.g., ethyl acetoacetate, with methyl thioglycolate (73) undergo the Dieckmann cyclization with alcoholic potassium hydroxide at lower temperatures to give ethyl 3-hydroxy-5-methyl-2-thiophenecarboxylate (74) in 75% yield. ° Besides ethyl acetoacetate, ethyl a-ethylacetoacetate, ethyl benzoyl acetate, and ethyl cyclopentanonecarboxylate were also used in this reaction/ It is claimed that /8-diketones, hydroxy- or alkoxy-methyleneketones, or /8-ketoaldehyde acetals also can be used in this reaction. From acetylacetone and thioglycolic acid, 3,5-dimethyl-2-thiophenecarboxyl-ic acid is obtained. ... 

A possible mechanism for the formation of the furanones 6 and 7 is illustrated in Scheme 2. The initial alkoxy radical generated from the alcohol 5 and lead tetraacetate (LTA) undergoes /3-scission to produce the acyl radical intermediate 9. Subsequent cyclization to 10 proceeds through attack of the radical at the carbonyl oxygen. The resulting Pb(IV) intermediate 11 finally collapses via the reductive... 

The starting materials for annulative cyclization are cycloalkenones that contain the allylsilane side chain in the 4-position. Such starting materials can easily be prepared from vinylogous esters40. Furthermore, reactions of 3-alkoxy-2-cyclohexenones with functionalized iodides in the presence of lithium diisopropylamide provides an excellent route to such precursors41 34 35. 

Dirhodhun (II) carboxylate catalyzed cyclization of a series of y-alkoxy-a-diazoesters has been shown to proceed with substantial diastereoselectrvity, producing the 2,3,5-trisubstituted tetrahydrofiirans. Hie diastereo selectivity of the cyclization improved as the electron-withdrawing ability of the substituent R increased (Scheme 22, <96JOC6706>). 

Stepanov et a/.143,144 report the ring opening of the monoxide (116) to several 2-oxaadamantane derivatives, where 116 is readily obtained by perbenzoic acid oxidation of 35. Treatment of 116 under various conditions yields different products. Thus, with aqueous acid it yields l-hydroxy-3-hydroxymethyl-2-oxaadamantane (117), with alcohols (R = CH3, C2H5) in acidic or basic media 1-alkoxy-substituted (118), and with hydrochloric acid l-chloro-3-hydroxymethyl-2-oxaadamantane(119). l-Methyl-2-oxaadaman-tane (120) is prepared by LAH reduction of the carbonyl group in 35 to alcohol 121 and subsequent cyclization with acid.140,142... 

Epoxides can also be reductively opened to form a radical. An example of an intramolecular cyclization of such a radical has recently been reported <06TL7755>. Treatment of 40 with Cp2TiCl generates an intermediate alkoxy radical, which then adds to the carbonyl of the formate ester. The product, 41, is formed as a 2 1 mixture of isomers at the anomeric carbon. This reaction is one of the first examples of a radical addition to an ester. The major byproduct of this reaction is the exo-methylene compound, 42, arising from a P-hydrogen elimination. 

Photochemical [2+2]cycloaddition between benzo[b]furan and 3-cyano-2-alkoxy-pyridines in benzene has been reported to follow a very interesting mechanism supported also by Frontier-MO calculations using the PM3 Hamiltonian. It is believed that the singlet excited state of the pyridine and the ground state benzofuran react to form a [2+2] adduct and is followed by ring opening to the cyclooctatriene, which cyclizes to the secondary endo- and exo-isomers shown below <00CC1201>. 

Very recently, Murakami has published an Rh(i)-catalyzed cyclization of 1,6-enynes triggered by addition of arylboronic acids (Scheme 74).281 Initial carborhodation of the alkyne moiety is followed by insertion into the alkene moiety. /3-Alkoxy elimination provides the final product 289 in good yield and regenerates the catalyst species. 

Cyclopentenones. 1,3-Dicarbonyl compounds add to enol ethers or esters (terminal) in the presence of Mn30(OAc)7 (excess) to form l-alkoxy-l,2-dihydro-furans. These can be converted to a 1,4-diketone, which undergoes aldol cyclization to fused (or spiro) cyclopentenones.1... 

In a more complex elaboration of the hydrogen atom abstraction/nucleo-philic cyclization route to tetrahydrofurans (Scheme 20), a carbohydrate-based N-alkoxy phthalimide was converted to a spirocyclic acetal in excellent yield and diastereoselectivity (Scheme 33) [136]. In this cyclization, nucleophilic attack takes place from the endo face of the trioxabicyclo [3.3.0] octane... 

As mentioned above, the reactivity of alkoxyallenes is governed by the influence of the ether function, which leads to the expected attack of electrophiles at the central carbon C-2 of the cumulene. However, the alkoxy group also activates the terminal double bond by its hyperconjugative electron-withdrawing effect and makes C-3 accessible for reactions with nucleophiles (Scheme 8.3). This feature is of particular importance for cyclizations leading to a variety of heterocyclic products. The relatively high CH-acidity at C-l of alkoxyallenes allows smooth lithiation and subsequent reaction with a variety of electrophiles. In certain cases, deprotonation at C-3 can also be achieved. 

Allenyl ethers are useful key building blocks for the synthesis of a-methylene-y-butyrolactones [129, 130], The synthesis of the antileukemic botryodiplodin was accomplished with the crucial steps briefly presented in Scheme 8.56. Bromoallenyl ethers 225 were easily prepared by base-induced isomerization from the corresponding /3-bromoalkyl alkynyl ether compounds and then subjected to electrophilic bro-mination with NBS. The resulting acetals 226 were converted into 2-alkoxy-3-methy-lenetetrahydrofurans 227 by dehydrohalogenation of the alkenyl bromide unit to an alkyne and subsequent radical cyclization employing tributyltin hydride [130],... 

In contrast to the rich chemistry of alkoxy- and aryloxyallenes, synthetic applications of nitrogen-substituted allenes are much less developed. Lithiation at the C-l position followed by addition of electrophiles can also be applied to nitrogen-containing allenes [10]. Some representative examples with dimethyl sulfide and carbonyl compounds are depicted in Scheme 8.73 [147, 157]. a-Hydroxy-substituted (benzotriazo-le) allenes 272 are accessible in a one-pot procedure described by Katritzky and Verin, who generated allenyl anion 271 and trapped it with carbonyl compounds to furnish products 272 [147]. The subsequent cyclization of 272 leading to dihydro-furan derivative 273 was achieved under similar conditions to those already mentioned for oxygen-substituted allenes. 

Ti-mediated cyclization of an allenynes having a leaving group provides a five-membered ring with cross-conjugated trienes which might be produced by the elimination of an alkoxy group from a titanacycle (Scheme 16.73) [79]. 

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