Cycloadditions zwitterion intermediate

The reactions of electrophilic alkenes (alkenes attached to electron-withdrawing groups) with enamines produce one or more of the following products simple alkylation (2), 1,2 cycloaddition (3), and 1,4 cycloaddition (4). Competition with C alkylation by N alkylation is inconsequential and therefore will be largely ignored (5,7). A stepwise ionic mechanism leading to these products necessarily involves the formation of a zwitterion intermediate (1) as the first step, which is then followed either by one of the... 

Olefins conjugated with electron-withdrawing groups other than a carbonyl group undergo reactions with enamines in a manner similar to the carbonyl-conjugated electrophilic alkenes described above. Namely, they condense with an enamine to form a zwitterion intermediate from which either 1,2 cycloaddition to form a cyclobutane ring or simple alkylation can take place. 

The initial reaction between a ketene and an enamine is apparently a 1,2 cycloaddition to form an aminocyclobutanone adduct (58) (68-76a). This reaction probably occurs by way of an ionic zwitterion intermediate (75). The thermal stability of this adduct depends upon the nature of substituents Rj, R2, R3, and R. The enolic forms of 58 can exist only if Rj and/or R4 are hydrogens. If the enamine involved in the reaction is an aldehydic enamine with no 3 hydrogens and the ketene involved is di-substituted (i.e., R, R2, R3, and R4 are not hydrogens), then the cyclo-butanone adduct is thermally stable. For example, the reaction of dimethyl-ketene (61) with N,N-dimethylaminoisobutene (10) in isopropyl acetate... 

Snider and coworkers125 have reported the Lewis acid catalyzed [2 + 2]cycloaddition of (phenylsulfonyl)allene 112. The reaction with methylenecyclohexane in dichloro-methane gives a 25% yield of an 8 1 mixture of 210 and 211 (equation 132). An addition reaction of l-(p-tolylsulfonyl)ethylene with enamines gives aminocyanobutanes via the zwitterionic intermediate (212) as shown in equation 133126. 

Stabilised sulphur ylides react with alkenylcarbene complexes to form a mixture of different products depending on the reaction conditions. However, at -40 °C the reaction results in the formation of almost equimolecular amounts of vinyl ethers and diastereomeric cyclopropane derivatives. These cyclopropane products are derived from a formal [2C+1S] cycloaddition reaction and the mechanism that explains its formation implies an initial 1,4-addition to form a zwitterionic intermediate followed by cyclisation. Oxidation of the formed complex renders the final products [30] (Scheme 8). 

A strong acceptor TCNE undergoes [2+2] rather than [4+2] cycloaddition reactions even with dienes. 1,1-Diphenylbutadiene [20] and 2,5-dimethyl-2,4-hexadiene (Scheme 5) [21] afford mainly and exclusively vinyl cyclobutane derivatives, respectively. In the reactions of 2,5-dimethyl-2,4-hexadiene (1) the observed rate constant, is greater for chloroform solvent than for a more polar solvent, acetonitrile (2) the trapping of a zwitterion intermediate by either methanol or p-toluenethiol was unsuccessful (3) radical initiators such as benzyl peroxide, or radical inhibitors like hydroquinone, have no effect on the rate (4) the entropies of activation are of... 

Such a stepwise reaction would not be expected to change the regiochemistry of cycloaddition, but it could lead to loss of stereospecificity if the zwitterionic intermediate has a long enough lifetime. In most reactions where only carbon-carbon bonds are being formed, the D-A reaction remains stereospecific. 

The stereochemistry of these reactions depends on the lifetime of the dipolar intermediate, which, in turn, is influenced by the polarity of the solvent. In the reactions of enol ethers with tetracyanoethylene, the stereochemistry of the enol ether is retained in nonpolar solvents. In polar solvents, cycloaddition is nonstereospecific, as a result of a longer lifetime for the zwitterionic intermediate.177... 

Reactions of 1 with epoxides involve some cycloaddition products, and thus will be treated here. Such reactions are quite complicated and have been studied in some depth.84,92 With cyclohexene oxide, 1 yields the disilaoxirane 48, cyclohexene, and the silyl enol ether 56 (Eq. 29). With ( )- and (Z)-stilbene oxides (Eq. 30) the products include 48, ( > and (Z)-stilbenes, the E- and Z-isomers of silyl enol ether 57, and only one (trans) stereoisomer of the five-membered ring compound 58. The products have been rationalized in terms of the mechanism detailed in Scheme 14, involving a ring-opened zwitterionic intermediate, allowing for carbon-carbon bond rotation and the observed stereochemistry. 

A theoretical study based on PM3 frontier molecular orbital (FMO) and potential energy surface (PES) analysis at the restricted Hartree-Fock (RHF)/6-31+G level was performed to examine the reaction of l-amino-2-ethoxycarbonyl-pyridinium mesitylenesulfonate and acrylonitrile in the presence of Hilnig s base leading to the formation of l,2-dihydropyrido[l,2-A]pyridazinium inner salt 17 <1999JOC9001>. The calculations indicated that both the [3+2] cycloaddition reaction and the ring expansion occurred in a concerted manner rather than through a stepwise mechanism via a zwitterionic intermediate 16 (Scheme 1). 

Decomposition of the diazo ester 395 in presence of dirhodium tetraacetate gives the zwitterionic intermediate 396, which undergoes a 1,3-dipolar cycloaddition with the double bond of the adjacent vinylindole. The bridged compound is isolated in good yield when the reaction is carried out at room temperature however, at 50 °C or above, compound 397 is the only compound isolated, again in good yield (Scheme 93) <2005JOC2206>. 

Cycloadditions give rise to four-membered rings. Thermal concerted [2+2] cycloadditions have to be antarafacial on one component and the geometrical and orbital constraints thus imposed ensure that this process is encountered only in special circumstances. Most thermal [2+2] cycloadditions of alkenes take place by a stepwise pathway involving diradical or zwitterionic intermediates [la]. Considerably fewer studies have been performed regarding the application of microwave irradiation in [2+2] cydoadditions than for other kinds of cydoaddition (vide supra). Such reactions have been commonly used to obtain /1-lactam derivatives by cycloaddition of ketenes with imines [18-20,117,118],... 

As noted above, formation of a furan [4 + 3]-cycloadduct during irradiation of a 4-pyrone was advanced as evidence for the zwitterionic intermediate. This process can be moderately efficient (equation 4)68, and can be envisioned as an approach to substituted cyclooctanoids. Besides the formation of three new carbon-carbon bonds, an additional attractive feature is the complete diastereoselectivity, arising from a compact [4 + 3]-cycloaddition transition state with approach from the face opposite the epoxide. However, the generality of the intermolecular reaction is limited, as competing [2 + 21-photodimerization, solvent trapping and rearrangement often predominate58. 

A different mode of cycloaddition occurs with 7-azabicyclo[2.2.1]-heptadiene derivatives, in which the nucleophilicity of the nitrogen atom determines the point of attachment of the electrophilic dienophile. The addition depicted in 87, which may occur in two steps via a zwitterionic intermediate rather than by a concerted mechanism, accounts for the structures (88) of 1 2 adducts obtained with A-methyl- or A-benzyl-pyrrole and dimethyl acetylenedicarboxylate. At a higher temperature the reaction with A-methylpyrrole also afforded the indole tetraester... 

The reaction of diazoazoles and isocyanates leading to azolo-tetra-zinones of type 258 (Scheme 75) can be regarded as a [7 -l- 2]cycloaddition of the diazoazoles to the electron-deficient hetero double-bond of the isocyanates (pathway a) or, alternatively, as a two-step reaction involving [3 -I- 2]cycloaddition of the diazoazoles to the isocyanates, leading to the spirostructure 259 and subsequent [l,5]acyl shift (pathway b). An additional two-step mechanism (pathway c) could involve nucleophilic attack by the azole ring nitrogen on the carbonyl isocyanate to give a zwitterionic intermediate that collapses to the [7 + 2]cycloadduct 258. 

Oxygenated dienes are exceptional substrates for vinylcarbenoids [78]. In order to avoid side-products derived from zwitterionic intermediates, nonpolar solvents are typically employed. A short synthesis of nezukone 57 highhghts the utiHty of the [3-1-4] cycloaddition for the synthesis of tropones (Scheme 14.4). The cycloaddition between the oxygenated butadiene 55 and 52 generates the cycloheptadiene 56 in 67% yield [78]. Treatment of 56 with Meli followed by acid-induced dehydration completes a very short synthesis of nezukone 57. 

A-Sulfinylamines (R—N=S=0) are known to function as reactive dienophiles and dipolarophiles, and some examples of [3 + 2] cycloaddition with thiocarbonyl ylides have been reported (176). For example, the reaction of thiobenzophenone (5)-methylide (16) with both A-phenyl and N-tosylsulfinylamines occurs regiose-lectively to give 1,3,4-dithiazolidine 3-oxides (135). In the case of thiocarbonyl ylide 69, reaction with N-phenyl sulfinylamine selectively afforded the analogous product 136 (R = Ph). However, the corresponding reaction with Al-tosyl sulfinylamine resulted in a mixture of the N,S-adduct (136) (R =Tos) and the 0,S-adduct 137. Formation of a mixture of products is compatible with a stepwise reaction via a zwitterionic intermediate. 

We were not able to obtain any cycloadduct from unactivated 2-azadienes 139 and esters of acetylenedicarboxylic acid. However, we found that 139 did cycloadd to typical electron-poor dienophiles such as esters of azodicarboxylic acid and tetracyanoethylene (Scheme 62). Thus, diethyl and diisopropyl azodicarboxylates underwent a concerted [4 + 2] cycloaddition with 139 to afford in a stereoselective manner triazines 278 in 85-90% yield (86CC1179). The minor reaction-rate variations observed with the solvent polarity excluded zwitterionic intermediates on the other hand, AS was calculated to be 48.1 cal K 1 mol-1 in CC14, a value which is in the range of a concerted [4 + 2] cycloaddition. Azadienes 139 again reacted at room temperature with the cyclic azo derivative 4-phenyl-1,2,4-triazoline-3,5-dione, leading stereoselectively to bicyclic derivatives 279... 

Ketene dimerization is the principal synthetic route to 4-methylene-2-oxetanones. This reaction proceeds very satisfactorily for ketene and methylketene, but disubstituted ketenes dimerize only to cyclobutane-1,3-diones. The cycloaddition reaction of r-butylcyanoketene to ketene and to methylketene gives a-cyanoalkylidene-/3-lactones in about 40% yield in addition to the cyclobutane-1,3-dione dimer of f-butylcyanoketene. A mechanism has been proposed for the formation of both types of dimers from a common zwitterionic intermediate (equation 111), with the relative amount of each product determined by the configurational equilibrium of the intermediate (80JOC4483, 75JOC3417). 

This method is by far the most successful and most widely used in the synthesis of four-membered heterocycles with two heteroatoms. In principle these formal additions can be envisioned to occur by (a) two displacements, (b) thermal concerted [2 + 2] cycloadditions, (c) photoinduced [2 + 2] additions, (d) stepwise zwitterionic intermediates or dipolar reactants, and (e) radical intermediates. In some cases the mechanisms have been elucidated but in many others the actual mode of addition is not known. For this reason, no attempt has been made to formally divide the latter four (b-e) into categories and only the first [(a), two displacement reactions] is covered separately. 

One of the most reactive electrophilic alkenes is l,l-dicyano-2,2-bis(trifluoromethyl)ethene which undergoes cycloadditions with enol ethers, thioenol ethers, ketene acetals and thioacetals even at temperatures as low as — 78 °C. The cyclobutancs are formed as the sole products of the reaction.37-38 The reactions arc regiospecific and highly stereoselective even though evidence for zwitterionic intermediates have been obtained. 

The observation of optical activity in the cycloaddition of TBCK with optically active cy-clonona-1,2-diene was taken as evidence for a concerted process.12 Subsequent studies on TBCK addition to optically active 1,3-dimethylallene and the observation of partially racemic mixtures of products13 indicated that these cycloadditions involve zwitterionic intermediates. Racemization is not necessarily the consequence of intermediate formation. 

Some of the earlier studies using partially resolved allenes (1,3-dimethylallene and l,3-di-/ert-butylailene) in cycloadditions with dimethylketene and terf-butylcyanoketene reported some asymmetric induction in the resulting 2-alkylidenecyclobutanones,2 3 however, no optical purity measurements were reported. Furthermore, these reactions arc of limited value due to partial racemization accompanying the intermediacy of zwitterionic intermediates (see Section 1.3.3.). 

More than one mechanism can account for the experimental observation of the Diels-Alder reaction.521,522,528 However, most thermal [4 + 2]-cycloadditions are symmetry-allowed, one-step concerted (but not necessarily synchronous) process with a highly ordered six-membered transition state.529 Two-step mechanisms with the involvement of biradical or zwitterion intermediates can also be operative.522,528... 

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