Intermolecular reactions ether formation

Cyclopropane formation occurs from reactions between diazo compounds and alkenes, catalyzed by a wide variety of transition-metal compounds [7-9], that involve the addition of a carbene entity to a C-C double bond. This transformation is stereospecific and generally occurs with electron-rich alkenes, including substituted olefins, dienes, and vinyl ethers, but not a,(J-unsaturated carbonyl compounds or nitriles [23,24], Relative reactivities portray a highly electrophilic intermediate and an early transition state for cyclopropanation reactions [15,25], accounting in part for the relative difficulty in controlling selectivity. For intermolecular reactions, the formation of geometrical isomers, regioisomers from reactions with dienes, and enantiomers must all be taken into account. 

The Pd-catalyzed intermolecular C—O bond formation has also been achieved [105-108]. Novel electron-rich bulky phosphine ligands utilized by Buchwald et al. greatly facilitated the Pd-catalyzed diaryl ether formation [109], When 2-(di-tert-butylphosphino)biphenyl (95) was used as the ligand, the reaction of triflate 93 and phenol 94 elaborated diaryl ether 96 in the presence of Pd(OAc)2 and K3PO4. The methodology also worked for electron-poor, neutral and electron-rich aryl halides. 

Muthusamy et al. (82) prepared a number of oxacyclic ether compounds from the tandem ylide formation-dipolar cycloaddition methodology. Their approach provides a synthetic tactic to compounds such as ambrosic acid, smitopsin, and linearol. Starting with either cyclopentane or cyclohexane templates, they prepared ylide sizes of five or six, which are trapped in an intermolecular cycloaddition reaction by the addition of DMAD. The products are isolated in good overall yield. In a second system, 2,5-disubstituted cyclohexenyl derivatives are utilized to generate the pendent ylide, then, A-phenylmaleimide is added in an intermolecular reaction, accessing highly substituted oxatricyclic derivatives such as 182 (Scheme 4.43). 

Such intermolecular or cross-linking ether formation can usually4-39 be held to the minimum by conducting the reaction at room temperature it... 

The reaction of diazo cation with phenolate yielding the azo dye may proceed through the formation of the diazo ether. Kekule came to this conclusion in 1870. Zollinger (1958), considering this conclusion, proposed and explained the mechanism by which the diazo ethers convert into the C-diazo compounds, that is, into the hydroxyazo dyes. The diazo ether preliminarily dissociates into the phenolate ion and the diazonium ion i.e., a two-stage intermolecular reaction takes place. The CIDNP effect suggests that the diazo ether may reversibly convert into the radical pair ... 

The Pd-catalysed intermolecular reaction of aryl bromides containing electron-withdrawing substituents with a wide variety of alcohols including MeOH, 2-propanol, benzyl alcohol and i-butyl alcohol gives the aryl ethers 416 under milder conditions than uncatalysed reactions. Bidentate ligands such as BINAP and DPPF (XLIX) are effective [206,207]. The aryl Pd alkoxide 417 was isolated as an intermediate, and the formation of the aryl ethers 418 by reductive elimination of 417 was confirmed. 

Because electrophilic aromatic substimtions have provided access to C-arylglycosides via intermolecular reactions, similar technology is available for effecting the intramolecular delivery of the aromatic species. For example, utilizing the furanosyl fluoride shown in Scheme 7.27, Araki et al. [115] achieved formation of an 83% yield of the bicyclic product on treatment with borontrifluoride etherate. Similar chemistry is known for methyl glycosides [116,117] and glycosyl acetates [118]. 

Among a host of other phosphine-catalysed reactions in which the initial step is the formation of a reactive phosphoniobetaine intermediate by addition to a carbon-carbon double or triple bond are intramolecular cyclisations leading to benzobicyclo[4,3,0]-compounds, " cyclic ethers " and lactones,and a great many intermolecular reactions, e.g., a [3 -b 3]-annulation of modified t-butyl allylic carbonates and alkylidenemalonitriles to give cyclohexenes,phosphine- (and fluoride)- catalysed routes to 1,4-benzothiazepines from cyclic sulfenamides and alkynes, a [4- -3]-annu-lation of allylic carbonates with methyl coumalate to give functionalised bicyclo[3.2.2]nonadienes, the a-carbon addition of cyanide ion, generated in situ from cyanohydrins, to activated alkynes, and a stereoselective... 

The intermolecular reaction of oxocarbenium ions with simple alkenes, less reactive carbon nucleophiles, is generally slow and inefficient. A recent paper has described that the (la)-promoted intermolecular reaction of acetals with vinylcyclopropane (22) gives 3,6-heptadienyl ethers (23) with high E selectivity [74]. The allylation mechanism involves the formation of a cyclopropylmethyl cation intermediate and its ring opening (Scheme 9.21). Homoallylstannane (24) also adds to the oxocarbenium ion generated from benzaldehyde dimethyl acetal and (la) [75]. 

Intramolecular [4-1-4]-photocycloaddition of 2-pyridones is accommodated with appropriate tether length and points of attachment (Scheme 5). When the tether is linked at the 3- and 6 - positions (45 and 49), it reinforces the preferred head-to-tail cycloaddition. With a three-atom chain, the cycloaddition of 45 yields a 2 1 mixture of trans- and cis-isomers, similar to the intermolecular reaction. A tether alcohol 45a has little effect on the formation of stereogenic centers during the cycloaddition and yields two diastereomers for both 46 and 47, epimeric at the alcohol carbon. Protection of the alcohol as the sterically demanding t-butyldimethylsilyl (TBS) ether (45h) leads to only 46 and 47. 

In the prostaglandin synthesis shown, silyl enol ether 216, after transmetaJ-lation with Pd(II), undergoes tandem intramolecular and intermolecular alkene insertions to yield 217[205], It should be noted that a different mechanism (palladation of the alkene, rather than palladium enolate formation) has been proposed for this reaction, because the corresponding alkyl enol ethers, instead of the silyl ethers, undergo a similar cyclization[20I],... 

Very recently a number of intermolecular a-amidoalkylation reactions related to the formation of C-C bonds with simple diastereoselection have been reported only activated 7t-nucle-ophiles, such as allylsilanes, enamines, enol ethers, etc. are used83 - 88. 

Intermolecular hydroalkoxylation of 1,1- and 1,3-di-substituted, tri-substituted and tetra-substituted allenes with a range of primary and secondary alcohols, methanol, phenol and propionic acid was catalysed by the system [AuCl(IPr)]/ AgOTf (1 1, 5 mol% each component) at room temperature in toluene, giving excellent conversions to the allylic ethers. Hydroalkoxylation of monosubstituted or trisubstituted allenes led to the selective addition of the alcohol to the less hindered allene terminus and the formation of allylic ethers. A plausible mechanism involves the reaction of the in situ formed cationic (IPr)Au" with the substituted allene to form the tt-allenyl complex 105, which after nucleophilic attack of the alcohol gives the o-alkenyl complex 106, which, in turn, is converted to the product by protonolysis and concomitant regeneration of the cationic active species (IPr)-Au" (Scheme 2.18) [86]. 

---