Carbon-oxygen bond formation reactions

C. Carbon- Oxygen Bond Formation Reactions C.l. Cyanoethylation of Alcohols... 

The carbon-oxygen bond formation follows the same pathway. For both nitrogen-carbon and oxygen-carbon bond formation, a competing reaction is 13-hydride elimination (if a hydride is present at the heteroatom fragment), which lowers the yield and the reduced arene is obtained after reductive elimination. Reductive elimination of the C-N or C-0 fragments should be faster than 13-hydride elimination in order to avoid reduction of the aryl moiety. The side-reaction is shown at the bottom of Figure 13.25. 

Carbon-Oxygen Bond Formation Hydroxyl or carboxylate groups can participate in a ring-closure reaction by an intramolecular nucleophilic attack to a generated electrophilic center as already described in Schemes 1 and 3. 

Carbon-Oxygen Bond Formation The cathodic reduction of some nitrocarhonyl compounds in aqueous acidic medium gives the hydroxylamino derivatives that can undergo a ring-closure reaction affording anthrandic compounds or isoxazolones [102-104] (Schemes 70 and 71). 

The anodic oxidation of catechol in the presence of 1,3-dimethylbarbituric acid was carried out in aqueous solution containing sodium acetate in an undivided cell at graphite and nickel hydroxide electrodes [114]. The results did not fit with the expected structure (Scheme 47, path A) but a dis-piropyrimidine was isolated in 35% yield (Scheme 47, path B). It seems that the initial attack of 1,3-dimethylbarbituric acid on the anodically formed o-quinone does not occur through the carbon-oxygen bond formation but rather through the carbon-carbon bond formation, giving rise to the final product via several consecutive reaction steps. 

This review is a summary of the work done and potential opportunities for inexpensive and easily accessible base catalysts, such as alkaline earth metal oxides and hydroxides, as well as alkali metals and oxides supported on alkaline earth metal oxides. Preparation methods of these materials, as well as characterization of basic sites are reported. An extensive review of their catalytic applications for a variety of organic transformations including isomerization, carbon-carbon and carbon-oxygen bond formation, and hydrogen transfer reactions is presented. 

The Tsuji-Trost-type reaction is applicable to bifunctional vinyl epoxide 144 and 1,3-diketone using a palladium catalyst as demonstrated by Koizumi, who obtained polymer 145 (Equation (67)). The reaction proceeds at 0 °C to a reflux temperature of THE. The resulting polymer 145 is isolated in a quantitative yield. The molecular weight of 145 is ca. 3000 (PDI = 2.0-2.7) when 5 mol% of Pd(PPh3)4 is employed as a catalyst. Use of Pd2(dba)3 with several bidentate phosphines such as dppe, dppp, dppb, and dppf is also effective for the polymerization reaction. Propargyl carbonate 146 also reacts with bisphenols in the presence of a palladium catalyst to afford polyethers 147 via carbon-oxygen bond formation at s - and r/) -carbon atoms (Equation (68)). 

These occur readily between electron-rich alkenes and electron-poor carbonyl compounds. The first example, reported in 1959 (64HC(19-2)729), was the formation of 4,4-diaryloxetane-2,2-dicarbonitriles by the room temperature reaction of 1,1-diarylethylenes and carbonyl cyanide. Continued investigation of this reaction shows that a telomerization product is also formed, the tetraphenylpentadienedinitrile (55) from 1,1-diphenylethylene and carbonyl cyanide. This may be interpreted to indicate that carbon-carbon bond formation may commence somewhat ahead of carbon-oxygen bond formation (75MI51302). This... 

The formation of oxygen heterocycles through carbon-oxygen bond formation was also reported. Substituted 2-(o-halophenyl)-ethanols were converted to dihydrobenzofuranes using palladium and Buchwald s bulky biaryl-type ligands (3.43.). The reaction was also efficient in the formation of six and seven membered oxygen heterocycles.53... 

Promising examples of the catalytic asymmetric Darzens condensation, which yields an epoxide product via carbon-carbon and carbon-oxygen bond formation, have been reported recently by two groups (Scheme 10.11). Toke and co-workers used crown ether 24 in the reaction to form the a,P-unsaturated ketone 78 [38b] with 64% ee, whereas the Shioiri group used the cinchona-derived salt 3a [52], which resulted in 78 with 69% ee. The latter authors propose a catalytic cycle involving generation of a chiral enolate in situ from an achiral inorganic base... 

If we consider reaction of mesylate ion with methyl bromide, we find that this is an endergic reaction thus the transition state lies along the reaction coordinate farther toward the products titan the reactants (Figure 5.11). The activated complex will therefore have a structure more resembling the products. There will be significant carbon-oxygen bond formation between the mesylate group and carbon and only a weak residual bond between carbon and bromine. The bromine... 

The reaction of organic radical cations have been the focus of much interest, and their synthetic reactions - including addition to alkenes and nucleophilic capture by alcohols resulting in carbon-carbon and carbon-oxygen bond formation, respec-... 

The rare earth triflates are used in three types of organic reactions, namely (i) carbon-carbon bond formation, (ii) carbon-oxygen bond formation and (iii) carbon-nitrogen bond formation. 

In a previous section (Section 2.4.5), it was noted that the photoreaction of aldehydes containing an asymmetric center adjacent to the carbonyl with furan results in the production of a 1 1 ratio of two exo photoproducts. Irradiation of 2-phenylpropanal and furan results in a nearly quantitative yield of exo photoproducts (245) and (246) in approximately a 1 1 ratio. This suggests a mechanism that is insensitive to the substitution pattern of the aldehyde one such mechanism is depicted in Scheme 25. Reaction of an excited carbonyl and the electron-rich furan proceeds with initial carbon-oxygen bond formation to pro-... 

Since the disclosures that the thermal dimerizations of acrolein and methyl vinyl ketone provide the 3,4-dihydro-2//-pyrans (1, 2) derived from 4ir and 2Tt participation of the a,3-unsaturated carbonyl compound in a Diels-Alder reaction, an extensive series of related observations have been detailed. This work has been the subject of several comprehensive reviews - - including the Desimoni and Tacco-ni extensive tabular compilation of work through 1974. Consequently, the prior reviews should be consulted for thorough treatments of the mechanism, scope, and applications of the [4 + 2] cycloaddition reactions of a,3-unsaturated carbonyl compounds. The [4 + 2] cycloaddition reactions of 1-oxa-1,3-butadienes with their 4-it participation in the Diels-Alder reaction exhibit predictable regioselectivity with the preferential or exclusive formation of 2-substituted 3,4-dihydro-2W-pyrans (equation 1). The exceptions to the predicted regioselectivity that have been observed involve the poorly matched [4 + 2] cycloaddition reaction of an electron-deficient l-oxa-l,3-butadiene with an electron-deficient dienophile, e.g. methyl crotonate or methacrolein. - Rigorous or simplified theoretical treatments of the [4 + 2] cycloaddition reaction of 1-oxa-1,3-butadienes predict the preferential formation of 2-substituted 3,4-dihy-dro-2f/-pyrans and accommodate the preferred endo approach of the reactants in which the carbon-carbon bond formation is more advanced than carbon-oxygen bond formation, i.e. a concerted but nonsynchronous [4 + 2] cycloaddition reaction. ... 

Bernard, K. A., Atwood, J. D. Evidence for carbon-oxygen bond formation, aldehyde decarbonylation, and dimerization by reaction of formaldehyde and acetaldehyde with trans-ROIr(CO)(PPh3)2. Organometallics 1988, 7, 235-236. 

Predictions based on rigorous or simplified theoretical calculations support the formation of the predominant 2-substituted 3,4-dihydro-2//-pyran regioisomer and accommodate a preferred endo approach of the reactants in which the carbon-carbon bond formation is more advanced than carbon-oxygen bond formation, i.e., a concerted but nonsynchronous [4 + 2] cycloaddition.5 15-20 Notable exceptions to the predicted regioselectivity of the Diels-Alder reactions of oxabutadienes have been observed, and without exception the examples have involved the poorly matched reaction of electron-deficient a,/3-unsaturated carbonyl compounds (An-component) with electron-deficient dienophiles (2tt component), e.g., methyl crotonate or methacrolein.5 2122... 

Carbon-Oxygen Bond Formation. CAN is an efficient reagent for the conversion of epoxides into /3-nitrato alcohols. 1,2-cA-Diols can be prepared from alkenes by reaction with CAN/I2 followed by hydrolysis with KOH. Of particular interest is the high-yield synthesis of various a-hydroxy ketones and a-amino ketones from oxiranes and aziridines, respectively. The reactions are operated under mild conditions with the use of NBS and a catalytic amount of CAN as the reagents (eq 25). In another case, N-(silylmethyl)amides can be converted to A-(methoxymethyl)amides by CAN in methanol (eq 26). This chemistry has found application in the removal of electroauxiliaries from peptide substrates. Other CAN-mediated C-0 bondforming reactions include the oxidative rearrangement of aryl cyclobutanes and oxetanes, the conversion of allylic and tertiary benzylic alcohols into their corresponding ethers, and the alkoxylation of cephem sulfoxides at the position a to the ester moiety. 

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