O-alkylation synthesis

Another variation of the Madelung synthesis involves use of an O-alkyl or O-silyl imidate as the C2 electrophile. The mechanistic advantage of this modification stems from avoiding competing N-deprotonation, which presumably reduces the electrophilicity of the amide group under the classical conditions. Examples of this approach to date appear to have been limited to reactants with a EW substituent at the o-alkyl group[15,16]. 

The a-hydioxypyiioles, which exist piimadly in the tautomeric pyiiolin-2-one form, can be synthesized either by oxidation of pyrroles that ate unsubstituted in the a-position or by ting synthesis. P-Hydtoxypyttoles also exist primarily in the keto form but do not display the ordinary reactions of ketones because of the contributions of the polar form (25). They can be teaddy O-alkylated and -acylated (41). 

The O-alkyl derivatives of those A-oxides, which exist partly or entirely as (V-hydroxy tautomers, may be made by primary synthesis (as above) or by alkylation. Thus, 5,5-diethyl-1-hydroxybarbituric acid (936 R = H) with methyl iodide/sodium ethoxide gives the 1-methoxy derivative (936 R = Me) or with benzenesulfonyl chloride/ethoxide it gives the alkylated derivative (936 R = PhS02) (78AJC2517). 

Purine, 2,6-dithioxo-1,2,3,6-tetrahydro-dethiation, 5, 558 Purine, 8-ethoxy-synthesis, 5, 577, 596 Purine, 6-ethoxycarbonylmethyl-nucleoside synthesis, 5, 561 Purine, 8-ethoxy-7-methyl-synthesis, 5, 577 Purine, 9-ethyl-synthesis, 5, 593 Purine, 6-fonnyl-reactions, 5, 547 synthesis, 5, 593 Purine, 8-fonnyl-reactions, 5, 547 Purine, 2-fluoro-synthesis, 5, 597 Purine, 6-fluoro-alkylation, 5, 529 synthesis, 5, 563, 573 Purine, 6-fluoro-9-methyl-reactions, with ammonia, 5, 562 Purine, 6-furfurylamino- — see Kinetin Purine, 9-glycofuranosyl-synthesis, 5, 572 Purine, 2-glycosyl-synthesis, 5, 587 Purine, 8-glycosyl-synthesis, 5, 585 Purine, 9-glycosyl-synthesis, 5, 572 Purine, 8-halo-synthesis, 5, 598 Purine, 2-hydrazino-synthesis, 5, 593 Purine, 8-o -hydroxyethyl-synthesis, 5, 574... 

Flavone formation is believed to proceed through a similar mechanism as the synthesis of chromones, albeit aromatic acid anhydrides and their corresponding salts are used. The first step is benzoylation of 12 to give the ester 14. Enolization and o-alkylation then affords the enolbenzoate 15. Enolbenzoate 15 then undergoes an acyl transfer to yield... 

Some representative Claisen rearrangements are shown in Scheme 6.14. Entry 1 illustrates the application of the Claisen rearrangement in the introduction of a substituent at the junction of two six-membered rings. Introduction of a substituent at this type of position is frequently necessary in the synthesis of steroids and terpenes. In Entry 2, formation and rearrangement of a 2-propenyl ether leads to formation of a methyl ketone. Entry 3 illustrates the use of 3-methoxyisoprene to form the allylic ether. The rearrangement of this type of ether leads to introduction of isoprene structural units into the reaction product. Entry 4 involves an allylic ether prepared by O-alkylation of a (3-keto enolate. Entry 5 was used in the course of synthesis of a diterpene lactone. Entry 6 is a case in which PdCl2 catalyzes both the formation and rearrangement of the reactant. 

Most alkoxy- or aryloxyquinoxalines have been made by primary synthesis (see Chapter 1), by alcoholysis or phenolysis of halogenoquinoxalines (see Sections 3.2.2 and 3.4.2), or by O-alkylation of tautomeric quinoxalinones or extranuclear hydroxyquinoxalines (see Sections 4.1.2.2 and 4.3.2). The remaining preparative routes are illustrated by the following classified examples. 

An important feature of the antibiotic chloramphenicol (9) is the presence of the dichloroacetamide function. Inclusion of this amide in a simpler molecule, teclozan (15), leads to a compound with antiamebic activity. Whether this is cause and effect or fortuitous is unclear. The synthesis begins with alkylation of the alkoxide derived from ethanolamine (10) with ethyl iodide to give the aminoether (11). Reaction of a,a -dibromo-p-xylene (12) with 2-nitropropane in the presence of base leads to dialdehyde (13). The reaction probably proceeds by O-alkylation on the nitropropyl anion... 

Monoanions derived from nitroalkanes are more prone to alkylate on oxygen rather than on carbon in reactions with alkyl halides, as discussed in Section 5.1. Methods to circumvent O-alkylation of nitro compounds are presented in Sections 5.1 and 5.4, in which alkylation of the a.a-dianions of primary nitro compounds and radial reactions are described. Palladium-catalyzed alkylation of nitro compounds offers another useful method for C-alkylation of nitro compounds. Tsuj i and Trost have developed the carbon-carbon bond forming reactions using 7t-allyl Pd complexes. Various nucleophiles such as the anions derived from diethyl malonate or ethyl acetoacetate are employed for this transformation, as shown in Scheme 5.7. This process is now one of the most important tools for synthesis of complex compounds.6811-1 Nitro compounds can participate in palladium-catalyzed alkylation, both as alkylating agents (see Section 7.1.2) and nucleophiles. This section summarizes the C-alkylation of nitro compounds using transition metals. 

Alkylation of cyclopropenones — effected by means of trialkyloxonium tetra-fluoroborates42,119) — leads to the easily hydrolyzable O-alkyl cyclopropenium cations 295, which are potential sources for triafulvene synthesis ... 

O-Alkylation of 4-hydroxy-3-morpholino-l,2,5-thiadiazole 132 has been achieved with the chiral cyclic chloro-methyl sulfite 133 which subsequently suffers ring opening on treatment with simple alcohols <2001RCB436> or alkylamines <2002RJ0213> to afford the timolol analogues 134 with very little racemization (Scheme 20). This indicated an almost exclusive attack of the oxy anion on the exocyclic carbon atom and is a significant improvement on the previous oxirane method, which suffers from racemization. An alternative biocatalytic asymmetric synthesis of (A)- and (R)-timolol has also appeared <2004S1625>. 

Still another possibility in the base-catalyzed reactions of carbonyl compounds is alkylation or similar reaction at the oxygen atom. This is the predominant reaction of phenoxide ion, of course, but for enolates with less resonance stabilization it is exceptional and requires special conditions. Even phenolates react at carbon when the reagent is carbon dioxide, but this may be due merely to the instability of the alternative carbonic half ester. The association of enolate ions with a proton is evidently not very different from the association with metallic cations. Although the equilibrium mixture is about 92 % ketone, the sodium derivative of acetoacetic ester reacts with acetic acid in cold petroleum ether to give the enol. The Perkin ring closure reaction, which depends on C-alkylation, gives the alternative O-alkylation only when it is applied to the synthesis of a four membered ring ... 

In general, nitronates undergo O-alkylation. However, some procedures have been developed that overcome the preference for O-alkylation in favour of C-alkylation. For example, the double deprotonated nitronates introduced by Seebach74 can be C-alkylated and this strategy was used for the synthesis of nitro furanosyl and pyranosyl compounds.75... 

Electron-deficient nitriles, such as for instance trichloroacetonitrile and trifluoroacetonitrile (A=B A = N B = CCC13, CCF3), are known to undergo direct and reversible, base-catalyzed addition of alcohols providing O-alkyl trichloroacetimidates (1,50). This imidate synthesis has the advantage that the free imidates can be isolated as stable adducts, which are less sensitive to hydrolysis than their corresponding salts. 

As the integrity of chiral alcohols are retained in the phase-transfer catalysed O-alkylation, the procedure is valuable for the synthesis of chiral ethers under mild conditions as, for example, in the preparation of alkoxyallenes via the initial formation of chiral propargyl ethers [8]. It has been proposed that a combination of 18-crown-6 and tetra-n-butylammonium iodide provide the best conditions for the O-benzylation of diethyl tartrate with 99% retention of optical purity [9]. 

One-pot synthesis of thioethers from potassium O-alkyl dithiocarbonate... 

Regiospecific mono-C-alkylation (60-90%) of trimethylsilyl enol ethers is promoted by benzyltriethylammonium fluoride [34, 35]. A similar alkylation of tin(IV) enolates is aided by stoichiometric amount of tetra-n-butylammonium bromide and has been utilized in the synthesis of y-iminoketones [36]. Carbanions from weakly acidic carbon acids can be generated by the reaction of their trimethylsilyl derivatives with tetra-n-butylammonium triphenyldifluorosilicate [37] (see also Section 6.3). Such carbanions react readily with haloalkanes. Tautomeric ketones in which the enol form has a high degree of stabilization are O-alkylated to form the enol ether, e.g. methylation of anthrone produces 9-methoxyanthracene [26],... 

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