Aldehydes cycloadditions with

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... 

On the other hand, the corresponding tin precursor (63) undergoes smooth cycloaddition with a wide variety of aldehydes to produce the desired methylene-tetrahydrofnran in good yields [32, 33]. Thus prenylaldehyde reacts with (63) to give cleanly the cycloadduct (64), whereas the reaction with the silyl precursor (1) yields only decomposition products (Scheme 2.20) [31]. This smooth cycloaddition is attributed to the improved reactivity of the stannyl ether (65) towards the 7t-allyl ligand. Although the reactions of (63) with aldehydes are quite robust, the use of a tin reagent as precursor for TMM presents drawbacks such as cost, stability, toxicity, and difficult purification of products. 

Keck et al. reported that a catalyst generated from (S)- or (l )-BINOL 12 and Ti(0-i-Pr)4 in a 2 1 ratio is more selective than the catalyst formed from a 1 1 mixture [19fj. The former catalyst was shown to catalyze the cycloaddition reaction of aldehydes 1 with Danishefsky s diene 2a affording the dihydropyrones 3 with moderate to excellent enantioselectivity (Scheme 4.12). The reaction proceeds well for different aldehydes with up to 97% ee and good yield of the cycloaddition products. 

Because ketones are generally less reactive than aldehydes, cycloaddition reaction of ketones should be expected to be more difficult to achieve. This is well reflected in the few reported catalytic enantioselective cycloaddition reactions of ketones compared with the many successful examples on the enantioselective reaction of aldehydes. Before our investigations of catalytic enantioselective cycloaddition reactions of activated ketones [43] there was probably only one example reported of such a reaction by Jankowski et al. using the menthoxyaluminum catalyst 34 and the chiral lanthanide catalyst 16, where the highest enantiomeric excess of the cycloaddition product 33 was 15% for the reaction of ketomalonate 32 with 1-methoxy-l,3-butadiene 5e catalyzed by 34, as outlined in Scheme 4.26 [16]. 

Selenoaldehydes 104, like thioaldehydes, have also been generated in situ from acetals and then directly trapped with dienes, thus offering a useful one-pot procedure for preparing cyclic seleno-compounds [103,104], The construction of a carbon-selenium double bond was achieved by reacting acetal derivatives with dimethylaluminum selenide (Equation 2.30). Cycloadditions of seleno aldehydes occur even at 0 °C. In these reactions, however, the carbon-selenium bond formed by the nucleophilic attack of the electronegative selenium atom in 105 to the aluminum-coordinated acetal carbon, may require a high reaction temperature [103], The cycloaddition with cyclopentadiene preferentially gave the kinetically favorable endo isomer. 

Transition-metal-based Lewis acids such as molybdenum and tungsten nitro-syl complexes have been found to be active catalysts [49]. The ruthenium-based catalyst 50 (Figure 3.6) is very effective for cycloadditions with aldehyde- and ketone-bearing dienophiles but is ineffective for a,)S-unsaturated esters [50]. It can be handled without special precautions since it is stable in air, does not require dry solvents and does not cause polymerization of the substrates. Nitromethane was the most convenient organic solvent the reaction can also be carried out in water. 

Cycloaddition reactions of the simple alkyl and aryl aldehydes 65 with (E)-l-methoxy-1,3-butadiene (18b) under high pressure conditions afforded adducts 66 and 67 in reasonable to good yields [2g, 23]. A marked preference for the c applying pressure enforces cnJo-addition (Scheme 5.5). Using mild Lewis-acid catalysts [24], such as Eu(fod)3, Yb(fod)3, or Eu(hfc)3, in combination with pressure, allows good results to be obtained with the added advantage of reducing the pressure to 10 kbar [25] (Scheme 5.5). 

Likewise, heating of aldehyde 445 with persilylated N-benzylglycine 446 in toluene leads, via the 0,N-acetal 447 and decarboxylation, to the intermediate 448 this cycUzes in 25% yield to the 1,3-dipolar cycloaddition product 449 [50] (Scheme 5.16). 

Trapping reactions of benzoylmethyleneoxophosphorane 39 a with carbonyl compounds dispel any remaining doubts as to the existence of acylated phosphenes. Unlike the diphenylmethyleneoxophosphorane 9, whose P/C double bond participates in cycloadditions, compound 39 a acts as a hetero-1,3-diene and undergoes [4 + 2]-cycloaddition with aldehydes and ketones 10 I7,35> it may again be assumed that the reaction is a two-step process involving 55 as intermediate. 

H(65)1889, 2005EJO3553>. Starting dihydro[l,2,4]triazolo[3, 4-4]benzo[l,2,4]triazines 482 readily react with aromatic aldehydes to yield iminium salts 483. These salts treated with a base (e.g., triethylamine) are deprotonated to reactive 1,3-dipolar azomethine imines 484. In contrast to related five-membered heterocycles, these compounds are relatively unstable on storage in the solid form and particularly in solution. Fortunately, this obstacle can be easily circumvented by their in situ preparation and subsequent 1,3-dipolar cycloaddition. These compounds can participate in 1,3-dipolar cycloadditions with both symmetric and nonsymmetric dipolarophiles to give the expected 1,3-cycloadducts in stereoselective manner. Selected examples are given in Scheme 82. 

Reaction of the aldehyde-tethered furanone 244 with pipecolinic acid results in the formation of the oxazolopyr-idine derivative 245, which undergoes spontaneous decarboxylation to give the ylide 246. This in turn undergoes an intramolecular cycloaddition with the tethered exomethylene group to give 247, or with the endocyclic alkene to give the furoindolizine 248 <1997T10633> (Scheme 66). 

To investigate the feasibility of employing 3-oxidopyridinium betaines as stabilized 1,3-dipoles in an intramolecular dipolar cycloaddition to construct the hetisine alkaloid core (Scheme 1.8, 77 78), a series of model cycloaddition substrates were prepared. In the first (Scheme 1.9a), an ene-nitrile substrate (i.e., 83) was selected as an activated dipolarophile functionality. Nitrile 66 was subjected to reduction with DIBAL-H, affording aldehyde 79 in 79 % yield. This was followed by reductive amination of aldehyde x with furfurylamine (80) to afford the furan amine 81 in 80 % yield. The ene-nitrile was then readily accessed via palladium-catalyzed cyanation of the enol triflate with KCN, 18-crown-6, and Pd(PPh3)4 in refluxing benzene to provide ene-nitrile 82 in 75 % yield. Finally, bromine-mediated aza-Achmatowicz reaction [44] of 82 then delivered oxidopyridinium betaine 83 in 65 % yield. 

The organotitanium compounds produced by desulfurization of the diphenyl thioacetals of aldehydes 28 with the titanocene(II) species Cp2Ti[P(OEt)3]2 29 react with carbon—carbon double bonds to form the olefin metathesis-type products. Thioacetals 28 may be transformed into terminal olefins by desulfurization with 29 under an ethene atmosphere (Scheme 14.15) [27]. This reaction is believed to proceed through a titanacyclobutane intermediate, formed by cycloaddition of the titanocene-alkylidene with ethene. 

The reaction of the aldehyde 256 with proline gave a product which was not the expected dihydiodibenz[r,f ]azepinc 257. Spectroscopic analysis revealed that this new product was an oxazolidine 259 (obtained as a single isomer) resulting from the 1,3-cycloaddition of the azomethine ylide 258 to the precursor aldehyde 256 (Scheme 38) <1999J(P1)2605>. 

Tandem nucleophilic substitution-[2+3] cycloaddition reaction of 4-bromo- and 4-toluenesulfonyloxy aldehydes 77 with sodium azide in DMF at 50 °C affords excellent yields (>80%) of substituted pyrrolo[.2.3.4]oxatriazoles 78 (Scheme 8) <2002HAC307>. 

Azomethine ylides. The reaction of 1 with the oxime of an aldehyde results in an iminium salt 2. Desilylation of 2 (CsF) gives rise to an azomethine ylide (a) that undergoes 1,3-dipolar cycloaddition with electron-deficient alkenes (equation I). 

In a series of important papers, MacMillan described the alkylation of electron rich aromatic and heteroaromatic nucleophiles with a,P-unsaturated aldehydes, using catalysts based upon the imidazoUdinone scaffold, further establishing the concept and utility of iminium ion activation. In line with the cycloaddition processes described above, the sense of asymmetric induction of these reactions can be rationalised through selective (F)-iminium ion formation between the catalyst and the a,P-unsaturated aldehyde substrate, with the benzyl arm of the catalyst blocking one diastereoface of the reactive Jt-system towards nucleophilic attack (Fig. 3). 

For arylsulfonyl methyl isocyanides (3), [3 + 2] cycloadditions with aldehydes yielding 4,5-disubstituted oxazoles (N) have been reported [115]. The cycloaddition takes place in the same manner as with the use of isocyano esters (A, = H) ... 

Also in 2009, an elegant combination of two original van Leusen reactions was reported, leading to a MCR toward 4,5-disubstituted oxazoles (19) [136]. The MCR involves the base-induced mono-alkylation of TosMIC (8a) followed by the formal cycloaddition with an aldehyde (Fig. 9). Although dialkylation is a problem often... 

An interesting entry to functionalized dihydropyrans has been intensively studied by Tietze in the 1990s using a three-component domino-Knoevenagel Hetero-Diels-Alder sequence. The overall transformation involves the transient formation of an activated heterodienophile by condensation of simple aldehydes with 1,3-dicarbonyls such as barbituric acids [127], Meldrum s acid [128], or activated carbonyls. In situ cycloaddition with electron-rich alkenes furnished the expected functionalized dihydropyrans. Two recent examples concern the reactivity of 1,4-benzoquinones and pyrazolones as 1,3-dicarbonyl equivalents under microwave irradiation. In the first case, a new three-component catalyst-free efficient one-pot transformation was proposed for the synthesis of pyrano-1,4-benzoquinone scaffolds [129]. In this synthetic method, 2,5-dihydroxy-3-undecyl-1,4-benzoquinone, paraformaldehyde, and alkenes were suspended in ethanol and placed under microwave irradiations to lead regioselectively the corresponding pyrano-l,4-benzoquinone derivatives (Scheme 38). The total regioselectivity was... 

The class of 3-silyl-substituted reagents provides, upon addition with aldehydes, allylic silanes that offer many options for further derivatization. Oxidative processes are described in previous sections (see the sections on Preparation of 1,2-Diols and 1,4-Diols). If the appropriate silicon substituents are chosen, formal [3+2] cycloadditions with aldehydes can be promoted under Lewis acid catalysis. For example, the mismatched addition of the Z-3-propyl-3-benzhydryldimethyl allylsilane 183 to an a-benzyloxy aldehyde proceeds with low diastereofacial selectivity in favor of product 184 however, after protection of the secondary alcohol, an efficient [3+2] annulation provides the polysubsubstituted furan 185 in good yield and acceptable stereoselectivity (Scheme 24). ° The latter is brought forward to a tricyclic unit found in the antitumor natural product angelmicin B. 

Intramolecular 1,3-dipolar cycloadditions have proven to be especially use fid in synthesis. The addition of nitrones to alkenes serves both to form a carbon-carbon bond and to introduce oxygen and nitrogen functionality.86 Entry 7 in Scheme 6.5 is an example. The nitrone B is generated by condensation of the aldehyde group with 7V-methylhydrox-ylamine and then goes on to product by intramolecular cycloaddition. 

---