Carbon dioxide cycloadditions

In addition there are certain other methods for the preparation such compounds. Upon heating of the thionocarbonate 2 with a trivalent phosphorus compound e.g. trimethyl phosphite, a -elimination reaction takes place to yield the olefin 3. A nucleophilic addition of the phosphorus to sulfur leads to the zwitterionic species 6, which is likely to react to the phosphorus ylide 7 via cyclization and subsequent desulfurization. An alternative pathway for the formation of 7 via a 2-carbena-l,3-dioxolane 8 has been formulated. From the ylide 7 the olefin 3 is formed stereospecifically by a concerted 1,3-dipolar cycloreversion (see 1,3-dipolar cycloaddition), together with the unstable phosphorus compound 9, which decomposes into carbon dioxide and R3P. The latter is finally obtained as R3PS ... 

Whereas electronically activated 2-pyrones can react thermally in both normal and inverse electron-demand Diels-Alder cycloaddition, 2-pyrone by itself requires thermal conditions that are so vigorous that they cause spontaneous extrusion of carbon dioxide from the bicyclic cycloadduct [61]. 

Table 6.14 Relative rates of cycloadditions of p-benzoquinone and cyclopentadiene in carbon dioxide...

The intramolecular cycloaddition of munchnone intermediates (derived from the cyclodehydration of A-acyl amino acids) with 1,3-dipolarophiles was employed to construct the mitomycin skeleton. Thus, heating alkynyl acids 23 with acetic anhydride forms the intermediates 24 which undergo cyclization with loss of carbon dioxide to afford the 4-oxo-tetrahydroindoles 25 <96TL2887>... 

A full development of the rate law for the bimolecular reaction of MDI to yield carbodiimide and CO indicates that the reaction should truly be 2nd-order in MDI. This would be observed experimentally under conditions in which MDI is at limiting concentrations. This is not the case for these experimements MDI is present in considerable excess (usually 5.5-6 g of MDI (4.7-5.1 ml) are used in an 8.8 ml vessel). So at least at the early stages of reaction, the carbon dioxide evolution would be expected to display pseudo-zero order kinetics. As the amount of MDI is depleted, then 2nd-order kinetics should be observed. In fact, the asymptotic portion of the 225 C Isotherm can be fitted to a 2nd-order rate law. This kinetic analysis is consistent with a more detailed mechanism for the decomposition, in which 2 molecules of MDI form a cyclic intermediate through a thermally allowed [2+2] cycloaddition, which is formed at steady state concentrations and may then decompose to carbodiimide and carbon dioxide. Isocyanates and other related compounds have been reported to participate in [2 + 2] and [4 + 2] cycloaddition reactions (8.91. 

The [2-I-2-I-2] cycloaddition reaction of diynes 40 and carbon dioxide 41 were successfully catalysed by a NHC-nickel (Scheme 5.12) [15]. The NHC-Ni complex was prepared in situ from [NiCCOD) ] and two equivalents of carbene. Pyrones 42 were obtained in excellent yields at atmospheric pressure of CO and mild reaction conditions. 

Pyridine compounds 45 can also be produced by the NHC-Ni catalysed cycloaddition between nitriles 43 and diynes 44 (Scheme 5.13) [16]. The SIPr carbene was found to be the best ligand for the nickel complex in this reaction. The reaction required mild reaction conditions and low catalyst loadings, as in the case of cycloaddition of carbon dioxide. In addition to tethered aUcynes (i.e. diynes), pyridines were prepared from a 3-component coupling reaction with 43 and 3-hexyne 23 (Scheme 5.13). The reaction of diynes 44 and nitriles 43 was also catalysed by a combination of [Ni(COD)J, NHC salts and "BuLi, which generates the NHC-Ni catalyst in situ. The pyridines 45 were obtained with comparable... 

The three-component reaction between isatin 432a, a-aminoacids 433 (proline and thioproline) and dipolarophiles in methanol/water medium was carried out by heating at 90 °C to afford the pyrrolidine-2-spiro-3 -(2-oxindoles) 51. The first step of the reaction is the formation of oxazlidinones 448. Loss of carbon dioxide from oxazolidinone proceeds via a stereospecific 1,3-cycloreversion to produce the formation of oxazolidinones almost exclusively with /razw-stereoselectivity. This /f-azomethine ylide undergo 1,3-dipolar cycloaddition with dipolarophiles to yield the pyrrohdinc-2-r/ V -3-(2-oxindolcs) 51. (Scheme 101) <2004EJ0413>. 

Phenylsydnone 89 is not restricted to [3+2] cycloaddition. Reaction of sydnone 89 and its derivatives with the substituted azete 90 gives isomeric l//-triazepines after extrusion of carbon dioxide (Equation 8). 

Photolysis of the triazepine products produces 2,2-dimethylpropanenitrile and the corresponding pyrazole in quantitative yield <1997BSF927>. Reaction of sydnone 89 with fulvene 91 proceeds by [ji4s + jt6s]-cycloaddition followed by spontaneous loss of carbon dioxide and a molecule of dimethylamine or acetic acid from the pseudo-azulene , cyclopentaMpyridazine 92 (Equation 9) <1996CC1011, 1997T9921>. 

The l,2,4-oxadiazolidin-5-ones 139 undergo retro-l,3-dipolar cycloaddition when heated in vacuum to give the nitrones 140. Treatment in acetonitrile in the presence of base results in attack of the exocyclic a-proton and fission of the N-O bond followed by loss of carbon dioxide and formation of the benzylidenaniline 141 in undisclosed yields via the mechanism shown in Scheme 16 <2006SC997>. 

Merlic demonstrated the direct, non-photochemical insertion of carbon monoxide from acylamino chromium carbene complexes 14 to afford a presumed chromium-complexed ketene 15 <00JA7398>. This presumed metal-complexed ketene leads to a munchnone 16 or munchnone complex which undergo dipolar cycloaddition with alkynes to yield the pyrroles 17 upon loss of carbon dioxide. 

FIGURE 8.20 Peptides activated at an IV-methylamino-acid residue are postulated to epimer-ize because of the formation of the oxazolonium ion. Evidence for the latter resides in spectroscopic studies,96 and the isolation of a substituted pyrrole that was formed when methyl propiolate was added to a solution of Z-Ala-MeLeu-OH in tetrahydrofuran 10 minutes after dicyclohexylcarbodiimide had been added.95 The acetylenic compound effected a 1,3-dipolar cycloaddition reaction (B), with release of carbon dioxide, with the zwitter-ion that was generated (A) by loss of a proton by the oxazolonium ion. 

An ytterbium binaphthol catalyst was successfully applied in the cycloaddition reactions of 3-carbomethoxy-2-pyrone (454) with O- and S-subsli luted olefins like 455 and 280d. Upon heating, the products lost carbon dioxide to yield chiral cyclohexadienes 456 (equation 136). S -substituted olefins generally gave higher ee values than the corresponding O-substituted ones. 

Nair and coworkers have described the [8 + 2] cycloaddition reactions of 2H-cyclohep-ta[fr]furan-2-ones such as 521 in several reports311. The reactions of 521 with alkenes yield azulene derivatives upon extrusion of carbon dioxide. Table 30 summarizes the results of the reactions between 521 and some 6,6-disubstituted fulvenes 522 (equation 151)311b. In the case of 6,6-dialkyl fulvenes 522a-c, the [8 + 2] cycloadducts 523 were the major adducts obtained, the Diels-Alder adducts 524 only being formed in trace amounts. 

The [8 + 2] cycloaddition reactions between substituted cyclohcpta h]furan-2-ones and enamines have been described by Kuroda and coworkers312. The cycloaddition reactions proceeded with concomitant elimination of carbon dioxide and amine. Thus, the reaction between 527 and enamine 528 afforded [8 + 2] cycloadduct 529 with good yield (equation 153)312c. 

In analogy with 143d, the 2-phenyl compound is obtained from tropone and 3-phenylsydnone in a low yield [93JCS(P1)1617]. The cycloaddition proceeds peri- and regioselectively in a [4it + 2tt] mode followed by extrusion of carbon dioxide from the primary adduct and spontaneous dehydrogenation. 

Cyclic amino acids 139, when heated in acetic anhydride, probably form initially mesoionic oxazolium 5-oxides (munchnones) subsequent 1,3-dip olar cycloaddition of 1,2-dicyanocyclobutene, loss of carbon dioxide, and opening of the cyclobutane ring lead to dinitriles 140 (80JHC1593). Pyridone 141 is the by-product (together with an indolizine) of the mono-cyclic pyridone dicarboxylate and acrylic ester (73JHC77). 

The addition to alkenes normally leads to unstable adducts that lose carbon dioxide under the reaction conditions. The intramolecular cycloaddition of the sydnone (30) takes place at room temperature, however (Equation (5)) and the cycloadduct (31) has been characterized <86HCA927>. The unstable species formed by the loss of carbon dioxide are also azomethine ylides. It is therefore possible for a second 1,3-dipolar addition to take place, as illustrated in Scheme 6 for the reaction of 3-phenylsydnone with Al-phenylmaleimide <86TL317,92JA8414>. This 2 1 addition has been used as the basis of a synthesis of polyimides. Imides of the type (32) were used as the dipolarophiles and their reaction with 3-phenylsydnone gave linear polymers <87MM726>. 

Anhydro-5-hydroxy-1,2,3,4-oxatriazolium hydroxides (4) are relatively stable at elevated temperatures under neutral and salt-free conditions. However, prolonged heating of (17) in the presence of lithium chloride gives rise to elimination of carbon dioxide with formation of an azide which can be trapped by 1,3-dipolar cycloaddition to an alkyne (Scheme 2) <68CB536>. 

Two synthetic routes to meso-ionic l,3-diazol-4-ones (91) have recently been reported. 1,3-Cycloaddition of phenyl isocyanate to the meso-ionic l,3-oxazol-5-one (94) yields the intermediate (95 or 96) from which carbon dioxide was extruded in boiling xylene, giving the meso-ionic l,3-diazoi-4-one (97). 

---