Acrolein, 2- cycloaddition reactions

A substituted a,/3-unsaturated aldehyde, cinnamaldehyde, has been observed to undergo the same type of two-step 1,3-cycloaddition reaction with a cyclohexanone enamine as acrolein does, forming in this case a stereo-isomeric mixture of substituted bicycloaminoketones in excellent yield (29a,31a,31b). 

In an investigation by Yamabe et al. [9] of the fine tuning of the [4-1-2] and [2-1-4] cycloaddition reaction of acrolein with butadiene catalyzed by BF3 and AICI3 using a larger basis set and more sophisticated calculations, the different reaction paths were also studied. The activation energy for the uncatalyzed reaction were calculated to be 17.52 and 16.80 kcal mol for the exo and endo transition states, respectively, and is close to the experimental values for s-trans-acrolein. For the BF3-catalyzed reaction the transition-state energies were calculated to be 10.87 and 6.09 kcal mol , for the exo- and endo-reaction paths, respectively [9]. The calculated transition-state structures for this reaction are very asynchronous and similar to those obtained by Houk et al. The endo-reaction path for the BF3-catalyzed reaction indicates that an inverse electron-demand C3-0 bond formation (2.635 A... 

The Lewis acid-catalyzed 1,3-dipolar cycloaddition reaction of nitrones to a,/ -un-saturated carbonyl compound in the presence of Lewis acids has been investigated by Tanaka et al. [31]. Ab-initio calculations were performed in a model reaction of the simple nitrone 18 reacting with acrolein 1 to give the two cycloadducts 19 and 20 (Scheme 8.7). 

Secondary orbital interactions (SOI) (Fig. 2) [5] between the non-reacting centers have been proposed to determine selectivities. For example, cyclopentadiene undergoes a cycloaddition reaction with acrolein 1 at 25 °C to give a norbomene derivative (Fig. 2a) [6]. The endo adduct (74.4%) was preferred over the exo adduct (25.6%). This endo selectivity has been interpreted in terms of the in-phase relation between the HOMO of the diene at the 2-position and the LUMO at the carbonyl carbon in the case of the endo approach (Fig. 2c). An unfavorable SOI (Fig. 2d) has also been reported for the cycloaddition of cyclopentadiene and acetylenic aldehyde 2 and its derivatives (Fig. 2b) [7-9]. The exo-TS has been proposed to be favored over the endo- IS. 

Two other applications of catalyst 364, i.e. in cycloaddition reactions of a-substituted acroleins with dienes 374 and 376, have been depicted in equations 110 and 111237. Cycloadducts 375 and 377 have been used as precursors in the syntheses of cassiol and gibberellic acid, respectively. The use of catalysts 364 and 369b in cycloadditions with acrolein resulted in low enantioselectivities with opposite face selectivities. 

Two approaches, based on furan, have found wide application in carbohydrate synthesis. Cycloaddition reactions of furan with 2-substituted acrylonitrile or acrolein lead to oxabicycloheptanes which, in tnm, can be transformed to monosaccharides. On the other hand, furfuryl alcohols can be converted—either by the Clauson-Kaas reaction or by mild oxidation—into 5,6-dihydro-4-pyrones, suitable for easy functionalization to sugars. 

Examples with 2-vinylindoles are also found. Thus, the reaction of N-methyl-2-(2-methoxyvinyl)indole, as a cis-trans mixture, with acrylonitrile and ethyl and methyl acrylate gives the corresponding Diels-Alder compounds [83IJC(B)846]. With N-methyl-2-(2-nitrovinyl)indole as diene, similar reactions occur with methyl acrylate, acrylonitrile, and acrolein acetal but in these cases, the fully aromatic compounds were isolated. The cycloaddition reaction with acrolein acetal was nonregioselective and the isolated adducts had a CHO group, indicating that the acetal had been hydrolyzed (presumably during work-up). 

The use of isoxazole derivatives in organic synthesis is of great interest, but little has been done on the utilization of such compounds as a part of a diene system in [4 + 2]-cycloadditions. 3-Methyl-5-vinylisoxazole 236 gave cycloaddition reactions in a sealed tube in benzene solution at 120°C for 3 days. With the dienophiles acrolein and methyl acrylate, aromatiza-tion of the isoxazole ring via a 1,3-proton shift occurs readily under the reaction conditions, allowing the direct isolation of compounds 237, which are also detected in the mass spectrum of the raw reaction material. The reactions are regioselective (85H2019). 

The second major route to tricyclic /3-lactams with a bridgehead nitrogen atom and extra heteroatom(s) is through cycloaddition reactions. Again, these may be of the intermolecular or intramolecular type. Diels-Alder reaction of acrolein and the cephems 420 gave 421 as the major products (Equation 65) <1996TL5967>. 

Scheme 18). The 1,3-pentadiene derivatives may be formed by an initial [2 + 2]-cycloaddition reaction, while the formation of the l-oxa-6-silacy-clohexene derivative can be explained by a direct [2 + 4]-cycloaddition reaction (98). It has been reported that the reaction of thermally generated silaethene derivatives with acrolein affords products that can be accounted for in terms of initial competing [2 + 2]- and [2 + 4]-cycloaddition reaction between the intermediates and acrolein (99). 

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. ... 

Figure 2 Thermal and (Lewis) acid catalyzed LUMOdjoe-controlled [4-I-2] cycloaddition reaction of acrolein and methyl vinyl ether AM I results (Table 5)...

In discussing pericyclic reactions so far, we have only been looking at the denominator of the third term of equation 2-7. However, the coefficients of the atomic orbitals also play their part. They particularly influence the regio-selectivity, the site-selectivity and the periselectivity of cycloaddition reactions. The former term refers to the orientation of a cycloaddition for example, methoxybutadiene (204) gives166 the ortho adduct (206) rather than the meta adduct (203) with acrolein (205). Site-selectivity and periselectivity,... 

If, in an early stage of the reaction, a second cyclopropene molecule is coordinated to the nickel, homo-cyclodimerization leading to tricyclic dimers of type 28 may also occur. To prevent the formation of 28, the stationary concentration of the cyclopropene in the reaction mixture must be small, i.e. the cyclopropene must be added slowly. This is especially critical if the electron-poor alkenes are only weakly bound, as is the case with methyl acrylate and the 3-alkyl-substituted acrylates. When acrolein or acrylonitrile are employed, the cycloaddition reaction is inhibited due to the formation of stable bis(alkene)nickel complexes. 

Since the thermal dimerizations of acrolein and methyl vinyl ketone were shown to provide the 3,4-dihydro-2//-pyrans l,12 an extensive range of related observations have been disclosed. This work has been the subject of several reviews.3 14 Only the work reported since the extensive Desimoni and Tacconi account5 of the Diels-Alder reaction of a,/3-unsatu-rated carbonyl compounds, 1-oxabutadienes bearing an oxygen atom at the diene terminus, has been detailed herein. The prior reviews should be consulted for an excellent discussion of the mechanism, scope, and application of the [4 + 2] cycloaddition reactions of a,/3-unsaturated carbonyl compounds as well as for extensive tabular compilations of the work through 1974.3-6... 

Bertrand et al. studied the 1,4-biradicals (16) expected in the model triplet [2h-2] photocycloaddition between acrolein and ethylene. According to their computations, the molecules first form the C-C bond on the triplet surface the system then imdergoes an intersystem crossing to the singlet siuface and either reverts into the reactants or completes the cycloaddition reaction. To rationalize the intersystem crossing step, they evaluated the spin-orbit coupling between singlet and triplet... 

Diels-Alder cycloaddition reaction between dihydropyran and acrolein over various H-form zeolites. 

The Diels-Alder cycloaddition reaction of dihydropyran with acrolein was performed in the presence of various H-form zeolites such as H-Faujasites, H-p, H-Mordenites which differ both in their shape selective as well as their acidic properties. The activity of the different catalysts was determined and the reaction products were identified. High 3delds in cycloadduct were obtained over dealuminated HY (Si/Al=15) and Hp (Si/Al=25) compared to HM (Si/Al=10). These results were accounted for in terms of acidity, shape selectivity and microporosity vs mesoporosity properties. The activity and the regioselectivity were then discussed in terms of frontier orbital interactions on the basis of MNDO calculations for thermal and catalyzed reactions by complexing the diene and the dienophile with Bronsted and Lewis acidic sites. From these calculations, Bronsted acidic sites appeared to be more efficient than Lewis acidic sites to achieve Diels-Alder reactions. 

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